CN110201278B - Medicine box for inhalation administration and inhalation administration combined structure - Google Patents

Abstract

The invention discloses a rotational flow generating device, a medicine box, an inhalation administration combined structure and an inhalation administration device. The rotational flow generating device is used for inhalation administration and comprises a rotational flow structure, the rotational flow structure is provided with an airflow inlet end, an airflow outlet end and a rotational flow channel arranged between the airflow inlet end and the airflow outlet end, the rotational flow channel comprises more than two rotational flow parts which are sequentially arranged from the center of the flow channel to the edge of the flow channel in a surrounding mode, and each rotational flow part is used for generating rotational flow for part of airflow input into the rotational flow part and then outputting the rotational flow. The rotational flow structure of the invention enables the airflow at different positions between the radial inner side of the flow channel and the radial outer side of the flow channel to generate rotational flow by arranging more than two rotational flow parts in the rotational flow channel in a surrounding way, so that the airflow at different positions in the whole flow channel can generate rotational flow, the atomization effect of the medicinal powder is improved, and the proportion of the medicinal powder inhaled into the lung is increased.

Description

Medicine box for inhalation administration and inhalation administration combined structure

Technical Field

The invention relates to the field of medical appliances, in particular to a medicine box for inhalation administration and an inhalation administration combined structure.

Background

Chronic obstructive pulmonary disease (chronic obstructive pulmonary disease) is a chronic lung disease characterized by airflow limitation that is not fully reversible. The world health organization estimates that chronic obstructive pulmonary disease is the third cause of death in our country, second only to tumors and cerebrovascular diseases.

The pulmonary inhalation is the first choice therapy of chronic obstructive pulmonary disease, and has the characteristics of targeting, high efficiency, quick acting, small toxic and side effects and the like. Common formulations for administration by inhalation include solution nebulization, metered dose nebulization and dry powder nebulization. Compared with solution atomization and metering atomization, the dry powder aerosol has good inhalation administration compliance, and is particularly suitable for patients with chronic obstructive pulmonary disease.

The inhalation administration device with the inhalation administration combined structure in the prior art has poor atomization effect on the medicinal powder and unsatisfactory inhalation administration effect.

Disclosure of Invention

The invention aims to provide a rotational flow generating device, a medicine box, an inhalation administration combined structure and an inhalation administration device, aiming at improving the effect of inhalation administration.

The invention provides a rotational flow generating device for inhalation administration, which comprises a rotational flow structure, wherein the rotational flow structure is provided with an airflow inlet end, an airflow outlet end and a rotational flow channel arranged between the airflow inlet end and the airflow outlet end, the rotational flow channel comprises more than two rotational flow parts which are sequentially arranged from the radial center of the flow channel to the edge of the flow channel in a surrounding manner, and each rotational flow part is used for generating rotational flow for part of airflow input into the rotational flow part and then outputting the rotational flow.

Further, the swirling portion includes at least one swirling vane.

Further, each swirl vane is fixedly arranged.

Furthermore, the swirl generating device also comprises an outer guide surface arranged outside the first swirl part counted from the edge of the flow passage.

Further, the outer flow guide surface is an expanding surface whose sectional area is gradually increased from the upstream to the downstream of the swirling flow passage at least on the side of the air flow outlet end.

Furthermore, an isolation structure for isolating the airflows of the two rotational flow parts is arranged between the adjacent rotational flow parts.

Further, the isolating structure comprises a first middle guide surface for guiding the airflow of the cyclone part close to the center of the two cyclone parts isolated by the isolating structure and/or a second middle guide surface for guiding the airflow of the cyclone part close to the edge of the two cyclone parts isolated by the isolating structure.

Further, at least one side of the airflow outlet end of the first middle flow guide surface is an expansion surface, the cross section area of which is gradually increased from the upstream to the downstream of the rotational flow channel; and/or the second intermediate flow guide surface is a divergent surface with the cross-sectional area gradually increased from the upstream to the downstream of the swirl passage at least on one side of the airflow outlet end.

A second aspect of the present invention provides a medicine cartridge including a powder-containing chamber for containing a powder, the medicine cartridge further including a swirling flow generating device of any one of the first aspect of the present invention for causing a swirling flow of an air flow for transporting the powder.

Further, the powder containing chamber has a first opening of the powder containing chamber for introducing an air flow for transporting the powder and a second opening of the powder containing chamber for discharging an air-powder mixture, and the swirling flow generating means is provided upstream of the first opening of the powder containing chamber to cause the air flow to generate a swirling flow before transporting the powder and transport the powder in a swirling flow state.

Furthermore, the medicine box also comprises a rectifying structure arranged at the downstream of the second opening of the medicine powder containing cavity.

Furthermore, the medicine box also comprises another rotational flow generating device which is arranged at the downstream of the second opening of the medicine powder containing cavity and generates rotational flow for the wind-powder mixture.

The third aspect of the invention provides an inhalation administration combination structure, which comprises an inhalation administration device and a medicine box matched with the inhalation administration device.

Further, the inhalation administration combination structure comprises another rotational flow generating device which is arranged at the downstream of the rotational flow generating device and generates rotational flow for the wind-powder mixture output by the medicine box.

A fourth aspect of the present invention provides an inhalation drug delivery device comprising the swirling flow generating device of any one of the first aspects of the present invention, the swirling flow generating device causing a swirling flow of an air flow for transporting the drug powder.

Further, the swirling flow generating means is for causing the air flow for transporting the powder to swirl before transporting the powder and transporting the powder in a swirling state.

Further, the inhalation drug delivery device further comprises another swirling flow generating means disposed downstream of the swirling flow generating means to generate a swirling flow of the air-powder mixture of the transported powder and the air-powder mixture of the transported powder.

Based on the rotational flow generating device, the medicine box with the rotational flow generating device, the inhalation administration device and the inhalation administration combined structure, the rotational flow generating device comprises a rotational flow structure, the rotational flow structure is provided with an airflow inlet end, an airflow outlet end and a rotational flow channel arranged between the airflow inlet end and the airflow outlet end, the rotational flow channel comprises more than two rotational flow parts which are sequentially arranged from the radial inner side to the radial outer side of the flow channel in a surrounding mode, and each rotational flow part is used for outputting partial airflow input into the rotational flow part after rotational flow is generated. The rotational flow structure of the invention enables the airflow at different positions between the radial inner side of the flow channel and the radial outer side of the flow channel to generate rotational flow by arranging more than two rotational flow parts in the rotational flow channel in a surrounding way, so that the airflow at different positions in the whole flow channel can generate rotational flow, the atomization effect of the medicinal powder is improved, and the proportion of the medicinal powder inhaled into the lung is increased.

Other features of the present invention and advantages thereof will become apparent from the following detailed description of exemplary embodiments thereof, which proceeds with reference to the accompanying drawings.

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 application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

FIG. 1 is a schematic perspective view of an angle of an inhalation delivery assembly according to an embodiment of the present invention;

FIG. 2 is a schematic perspective view of another angle of an inhalation delivery assembly according to an embodiment of the present invention;

FIG. 3 is an exploded view of the inhalation delivery assembly shown in FIG. 1;

FIG. 4 is a schematic structural view of the cartridge of FIG. 3;

fig. 5 is a schematic view of an angle of the first and second receiving division bodies of fig. 3;

fig. 6 is a structural view of another angle of the first and second receiving division bodies of fig. 3;

FIG. 7 is a schematic structural view of each first swirling structure of FIG. 3;

FIG. 8 is a schematic view of a first swirling structure of FIG. 3;

FIG. 9 is a schematic structural view of the turntable in FIG. 3;

FIG. 10 is a schematic view of another angular configuration of the turntable shown in FIG. 9;

FIG. 11 is a schematic structural view of the elastic member of FIG. 3;

FIG. 12 is a schematic view of the detent disc of FIG. 3;

FIG. 13 is a schematic structural view of the mounting plate of FIG. 3;

FIG. 14 is a schematic structural view of the retainer plate of FIG. 3;

FIG. 15 is a schematic structural view of the outer ring of the turntable in FIG. 3;

FIG. 16 is a schematic structural view of the marker disk of FIG. 3;

FIG. 17 is a schematic structural view of the first housing of FIG. 3;

FIG. 18 is a schematic structural view of the second housing of FIG. 3;

FIG. 19 is a schematic view of the trachea of FIG. 3;

FIG. 20 is a schematic view of the nozzle of FIG. 3 in one orientation;

figure 21 is a schematic view of the suction nozzle of figure 3 in another orientation.

Each reference numeral represents:

1-a first housing; 1A-vent; 2-a second housing; 2A-the opening of the first medicine box placing cavity; 3-a box body; 3A-an air inlet; 3B-air powder outlet; 31-inner ring wall of the box body; 32-outer ring wall of the box body; 33-a first end wall; 33A-vias; 34-a second end wall; 4-a first containing split body; 5-a first swirl structure; 6-a second containing split body; 61-receptacle ratchet; 6A-a rotating shaft; 7-mounting a disc; 71-a connecting strip; 8-a logo disc; 9-a ratchet plate; 91-pawl plate pawl; 92-connecting projections; 10-outer ring of the turntable; 10A-window; 11-a limiting disc; 11A-a limit groove; 11B-a second connecting groove; 12-a resilient element; 13-a turntable; 13A-first connecting groove; 131-a turntable pawl; 132-a limit projection; 15-trachea; 151-a rectifying structure; 16-a suction nozzle; 16A-wind powder suction port; 16B-peripheral air suction ports; 17-a gas tube connection; 18-a mouthpiece cover; 19-second swirl structure.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The relative arrangement of the components and steps, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective portions shown in the drawings are not drawn in an actual proportional relationship for the convenience of description. Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

In the description of the present invention, it should be understood that the terms "first", "second", etc. are used to define the components, and are used only for the convenience of distinguishing the corresponding components, and if not otherwise stated, the terms have no special meaning, and thus, should not be construed as limiting the scope of the present invention.

In the description of the present invention, it is to be understood that the orientation or positional relationship indicated by the orientation words such as "front, rear, upper, lower, left, right", "lateral, vertical, horizontal" and "top, bottom", etc. are usually based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplicity of description, and in the case of not making a reverse description, these orientation words do not indicate and imply that the device or element being referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore, should not be considered as limiting the scope of the present invention; the terms "inner and outer" refer to the inner and outer relative to the profile of the respective component itself.

The rotational flow generating device for inhalation administration of the embodiment of the present invention includes a rotational flow structure. The cyclone structure is provided with an airflow inlet end, an airflow outlet end and a cyclone channel arranged between the airflow inlet end and the airflow outlet end, the cyclone channel comprises more than two cyclone parts which are sequentially arranged from the center of the flow channel to the edge of the flow channel in a surrounding mode, and each cyclone part is used for outputting part of airflow input into the cyclone part after generating cyclone. According to the rotational flow structure provided by the embodiment of the invention, more than two rotational flow parts which are arranged in a surrounding manner are arranged in the rotational flow channel, so that airflow at different positions between the radial inner side of the flow channel and the radial outer side of the flow channel of the rotational flow channel can generate rotational flow, the airflow at different positions in the whole flow channel can generate rotational flow, the suction effect on the medicinal powder is improved, and the proportion of the medicinal powder sucked into the lung is increased.

Preferably, the direction of the rotational flow generated by at least two adjacent rotational flow portions is opposite. The direction of the rotational flow generated by the adjacent rotational flow parts is set to be opposite, so that the airflow before the medicine powder is blown forms rotational flows in different directions, and the directions of impact forces to the medicine powder are also different, so that the medicine powder can be better sucked out of the medicine box and can be more easily absorbed by a patient.

The structure of the swirling flow generating device, and the structure of the medicine cartridge, the inhalation device and the inhalation-administration combination structure having the swirling flow generating device according to the embodiment of the present invention will be described in detail with reference to fig. 1 to 21.

The medicine cartridge of the present embodiment has a medicine powder containing chamber for containing medicine powder. The inhalation delivery device is used for sucking the medicinal powder in the medicinal powder containing chamber.

The inhalation-drug delivery combined structure of the present embodiment comprises two swirling flow generating means, the first swirling flow generating means being provided at a position where a swirling flow can be generated in an air flow before blowing the drug powder, and the second swirling flow generating means being provided at a position where a swirling flow can be generated in the air-powder mixture. Wherein, first whirl produces the device and includes first whirl structure. The second rotational flow generating device comprises a second rotational flow structure. Of course, in other embodiments, the first swirling device may also include the second swirling structure. The second swirling flow generating means may comprise a first swirling structure.

As shown in fig. 3, 7 and 8, the first swirling structure of the present embodiment is a circular structure. The first swirling structure 5 of the present embodiment has an airflow inlet end, an airflow outlet end, and a swirling flow passage provided between the airflow inlet end and the airflow outlet end. The swirl passage comprises more than two swirl parts which are sequentially arranged from the radial inner side of the flow passage to the radial outer side of the flow passage in a surrounding manner, and each swirl part is used for generating swirl on part of airflow input into the swirl part and then outputting the swirl part. The first cyclone structure 5 of this embodiment is through set up the more than two whirl portions of encircleing arranging in the whirl passageway for the air current homoenergetic that is in the whirl passageway at the radial inboard of runner to the different positions between the radial outside of runner can produce the whirl, consequently is located the air current homoenergetic of different positions in whole runner and can produce the whirl, improves the atomization effect to powder.

In other embodiments not shown in the figures, the first swirling structure may also be a square structure or the like.

Preferably, the direction of the rotational flow generated by at least two adjacent rotational flow portions is opposite. The direction of the rotational flow generated by the adjacent rotational flow parts is set to be opposite, so that the rotational flow in different directions is formed by the airflow before the medicine powder is blown, the direction of the impact force to the medicine powder is also different, and the medicine powder can be better atomized into smaller powder and is easier to be absorbed by a patient.

Specifically, as shown in fig. 8, the first swirling structure 5 of the present embodiment includes a first swirling portion 51 and a second swirling portion 52. The first swirling flow portion 51 and the second swirling flow portion 52 generate swirling flows in opposite directions. The first swirling structure 5 of the present embodiment sets the direction of the swirling flow generated by the adjacent swirling portions to be reverse, so that the airflow before blowing the powder forms swirling flows in different directions, and the direction of the impact force on the powder is also different, thereby better blowing the powder and improving the suction effect of the powder.

Preferably, the direction of the swirling flow generated by the first swirling flow portion counted from the outside of the flow passage is opposite to the direction of the swirling flow generated by the second swirling flow portion counted from the outside of the flow passage. The direction of the rotational flow that two rotational flow portions that will be located the radial outermost side of rotational flow runner produced sets up to opposite for the rotational flow of the radial outermost side's of rotational flow runner air current is bigger, thereby makes the bigger air current of this part rotational flow can strike powder better and hold the powder on the chamber wall in chamber after getting into powder and holding the intracavity, reduces remaining of powder, the increase gets into the internal powder proportion of patient.

Preferably, in order to generate rotational flow for the airflow at different positions in the circumferential direction of the rotational flow passage, the rotational flow portion of the present embodiment includes at least one rotational flow blade.

In order to maintain the amount of the powder inhaled per time to be stable, each of the swirl vanes of the present embodiment is fixedly provided.

Preferably, the first swirling structure 5 further includes an outer guide surface provided outside the first swirling portion from the outside of the flow passage. The outer guide surface is an expanding surface gradually enlarged from the upstream to the downstream of the swirl passage at least on one side of the airflow outlet end. Outside water conservancy diversion face sets up to the expansion face and does benefit to and makes the air current strike the powder that is located the chamber wall department that powder held the chamber to reduce powder and remain, increase the powder volume that gets into in the patient oral cavity.

In particular, in this embodiment, the flared surface includes a conical surface configuration.

Preferably, in order to avoid the mutual influence of the airflows between two adjacent swirling portions, as shown in fig. 8, an isolation structure 52 for isolating the airflows of the two swirling portions is provided between the adjacent swirling portions of the present embodiment.

Preferably, the separating structure 52 includes a first intermediate flow guide surface for guiding the airflow of the inner one of the two swirling portions separated therefrom and a second intermediate flow guide surface for guiding the airflow of the outer one of the two swirling portions separated therefrom.

Specifically, the first intermediate flow guide surface is an expanding surface whose sectional area gradually increases from the upstream to the downstream of the swirling flow passage at least on the side of the air flow outlet end, and the second intermediate flow guide surface is an expanding surface whose sectional area gradually increases from the upstream to the downstream of the swirling flow passage at least on the side of the air flow outlet end. The arrangement of the expansion surface can also enable the airflow to impact the medicine powder on the cavity wall of the medicine powder containing cavity, so that the medicine powder amount entering the oral cavity of the patient is increased.

The medicine box of this embodiment has more than two powder and holds the chamber. As shown in fig. 7, the first swirling flow generating device of the present embodiment includes two or more first swirling flow structures 5 provided corresponding to two or more powder holding chambers. For ease of assembly, more than two first swirl structures 5 may be connected together.

The first rotational flow generating device of the present embodiment is disposed in the cartridge. Specifically, the first swirling flow generating means is provided upstream of the powder containing chamber of the medicine cartridge. In order to better explain the matching relationship between the first swirling flow generating device and the cartridge, the structure of the cartridge of this embodiment will be described in detail below.

As shown in fig. 1 to 8, the medicine cartridge of the present embodiment includes a cartridge body 3 and a medicine powder containing body. The medicine powder containing body is arranged in the box body 3 and is provided with a medicine powder containing cavity for containing medicine powder. The powder containing chamber includes a first opening of the powder containing chamber and a second opening of the powder containing chamber. The box body 3 is provided with an air inlet 3A for introducing external air into the box body 3 and an air-powder outlet 3B for outputting an air-powder mixture. The medicine powder containing body is movably disposed with respect to the case body 3 to switch the medicine powder containing chamber between a closed state and an open state. In the closed state, the case body 3 closes the first opening of the powder containing chamber and the second opening of the powder containing chamber. In the open state, the first opening of the powder holding chamber communicates with the air inlet 3A, and the second opening of the powder holding chamber communicates with the air powder outlet 3B so that the powder can be sucked out from the air powder outlet together with the outside air introduced into the air inlet under the suction force of the air powder outlet.

In the present embodiment, the medicine powder containing body is rotatably provided with respect to the case body 3 so that the medicine powder containing chamber is switched between the closed state and the open state. The powder container can be rotationally arranged relative to the box body in the embodiment, so that the volume of the medicine box is small, and the medicine box is favorable for storage and carrying. The powder holding chamber may be arranged, for example, radially, axially, at an angle to the radial direction, at an angle to the axial direction, or the like.

In the present embodiment, specifically, the medicine powder containing body is coaxially and rotatably provided with respect to the case body 3. as shown in fig. 4, the case body 3 comprises an annular case body. The annular box body comprises a first box body annular wall, a second box body annular wall and an installation space formed between the first box body annular wall and the second box body annular wall. The air inlet 3A is arranged on the annular wall of the first box body, and the air powder outlet 3B is arranged on the annular wall of the second box body. The medicine powder containing body is arranged in the installation space. The powder container has a first container circumferential wall and a second container circumferential wall. The powder holds the chamber and is located first and hold between the body rampart and the second and hold between the body rampart, and the powder holds the first opening in chamber and sets up on the first body rampart that holds, and the powder holds the second opening in chamber and sets up on the second body rampart that holds. The medicine box of this embodiment sets up box body 3 to annular box body and holds the body with the powder and set up in the installation space between first box body rampart and the second box body rampart and make the compact structure of medicine box of this embodiment.

In this embodiment, the first box body annular wall is a box body annular wall 31 located at the radial inner side of the annular box body. The second box body annular wall is a box body outer annular wall 32 located at the radial outer side of the annular box body. In other embodiments, the first cassette annular wall may be located radially outwardly of the annular cassette and the second cassette annular wall may be located radially inwardly of the annular cassette.

Preferably, the air inlet 3A and the air powder outlet 3B are provided in the same direction in the radial direction of the case 3. The powder containing chamber extends in a radial direction of the powder containing body. When a patient needs to suck the medicine powder, the medicine powder containing body is controlled to rotate relative to the box body 3 so as to communicate the medicine powder containing cavity with the air inlet and the air powder outlet. When the patient does not need to suck the medicine powder, the medicine powder containing body is controlled to rotate relative to the medicine powder containing chamber to a position closed by the medicine powder containing chamber 3.

As shown in fig. 4, in this embodiment, the annular case further includes a first end wall 33 disposed on the inner annular wall 31 of the case, the powder holding body is rotatably connected to the first end wall 33, and the first end wall 33 and the inner annular wall 31 of the case form an air inlet chamber communicating with the air inlet 3A. The arrangement of the air inlet cavity enables a space to exist between the external space of the inhalation drug delivery combined structure and the air inlet 3A, and the arrangement of accessories such as a filtering structure and a flow equalizing structure is facilitated.

In particular, the annular box comprises a second end wall 34 disposed between the box inner annular wall 31 and the box outer annular wall 32. The box body inner annular wall 31, the box body outer annular wall 32 and the second end wall 34 enclose an annular groove, and the annular groove forms an installation space. The second end wall 34 and the first end wall 33 are disposed at both axial ends of the box body 3.

In an embodiment not shown in the drawings, the powder containing body may also be arranged translatably in relation to the cartridge. For example, the powder containing body and the cartridge are each a cubic structure, and the powder containing body is disposed in the cartridge and translatably disposed along the length direction of the cartridge.

In the present embodiment, as shown in fig. 5 and 6, the medicine powder containing body includes a first containing division body 4 and a second containing division body 6. The first sub-chamber that holds is equipped with on the first components of a whole that can function independently 4 that holds, the second holds and is equipped with the second on the components of a whole that can function independently 6 and holds the sub-chamber. The first branch chamber that holds 4 and the second of the components of a whole that can function independently 6 locks messenger corresponding position holds with the second and holds the branch chamber and form powder jointly and hold the chamber. The powder of this embodiment holds the body components of a whole that can function independently and sets up the components of a whole that can function independently that holds that two mutual locks make things convenient for the powder to hold the partial shipment of the powder in chamber.

The powder holding chamber of this embodiment is a cylindrical chamber structure, and in other embodiments not shown in the drawings, the powder holding chamber may be configured in other shapes, such as a cubic structure.

Preferably, in order to make the fastening between the first accommodating split body 4 and the second accommodating split body 6 more firm, one of the first accommodating split body 4 and the second accommodating split body 6 is provided with a connecting column, and the other is provided with a connecting hole, and the connecting column is inserted into the connecting hole so that the first accommodating split body 4 and the second accommodating split body 6 are fastened tightly with each other.

Specifically, in this embodiment, as shown in fig. 5 and 6, the first accommodating split body 4 is provided with both a connection column and a connection hole, and correspondingly, the second accommodating split body 6 is provided with both a connection column that is matched with the connection hole provided in the first accommodating split body 4 and a connection hole that is matched with the connection column provided in the first accommodating split body 4. The arrangement is such that the fitting between the first and second accommodation division bodies 4 and 6 is tighter.

Furthermore, the connecting column of the embodiment is of a circular structure, and the connecting hole is of a square structure. The arrangement facilitates the combination of the medicine powder containing body.

Specifically, the first accommodation component 4 of the present embodiment is of an annular structure and is sleeved outside the box inner wall 31 of the box body 3. The second accommodation division body 6 is engaged with the first accommodation division body 4 and is disposed on the first end wall 33. As shown in fig. 4, the first end wall 33 is provided with a through hole 33A. The second holds and is provided with axis of rotation 6A on the components of a whole that can function independently 6, and axis of rotation 6A wears to locate in through-hole 33A so that the second holds the components of a whole that can function independently 6 rotatable for box body 3, because the first body of a whole that can function independently 4 holds with the second holds components of a whole that can function independently 6 interconnect, therefore the second holds the components of a whole that can function independently 6 and rotates and can drive the first body of a whole that can function independently 4 synchronous revolution for box body 3.

Preferably, the powder containing body of this embodiment includes two or more powder containing chambers. More than two powder of medicine box of this embodiment hold the chamber and can hold many doses of powder, and the patient can rotate so that more than two powder hold the chamber and be in open state and then aspirate the powder in different powder hold chamber in proper order through control powder holding body relative to box body 3 when using the medicine box of this embodiment to inhale and dose. At the moment, more than two medicine powder containing cavities can be used for containing different kinds of medicine powder and can also be used for containing the same kind of medicine powder. For example, when the same kind of powder is placed in two or more powder-containing chambers, the patient can sequentially suck the powder in the different powder-containing chambers according to the amount of the powder to be used for dosing. When different kinds of medicinal powder are placed in more than two medicinal powder containing cavities, the patient can suck according to the dosage of different medicinal powder. The kit of this embodiment is therefore convenient for the patient to administer.

Fig. 5 and 6 schematically show that the powder containing body of the medicine cartridge has seven powder containing chambers, and the powder containing body is rotatably provided with respect to the case body 3 such that the seven powder containing chambers are sequentially communicated with the air inlet port 3A and the air outlet port 3B.

In the present embodiment, the first swirling structure 5 is provided at the air inlet 3A. In order to facilitate the guarantee of the sealing property of the medicine powder containing cavity and make the air flow entering the medicine powder containing cavity more concentrated, the end face of the air flow inlet end of the first rotational flow structure 5 is in contact with and matched with the end face of the air inlet of the medicine box in shape. The first cyclone structure 5 of this embodiment is disposed at the air inlet 3A of the case 3, the end face of the air inlet end of the first cyclone structure 5 is in contact fit with the case 3, and the end face of the air outlet end of the first cyclone structure 5 is in contact fit with the powder containing body.

In this embodiment, the first box body annular wall of the box body 3 is a cylindrical structure, so as shown in fig. 8, the end surface of the airflow inlet end of the first rotational flow structure 5 is set to be a cylindrical arc structure protruding to the airflow outlet end side.

The medicine cartridge of the present embodiment includes a cartridge body 3 and a medicine powder containing body. The powder containing body has two or more powder containing chambers and is rotatably provided with respect to the cartridge body 3. And a first rotational flow structure 5 is arranged at the air inlet 3A of the box body 3. The patient can rotate relative to the box body through controlling the powder container when using the medicine box of this embodiment in order to aspirate the powder in different powder container chambers, therefore the medicine box of this embodiment makes things convenient for the patient to use medicine. In addition, the medicine box of the embodiment enables the airflow to generate rotational flow before the medicine powder is blown by arranging the first rotational flow structure at the air inlet so as to fully atomize the medicine powder, thereby increasing the proportion of the medicine powder inhaled into the lung.

The second rotational flow generating device of the embodiment of the invention comprises a second rotational flow structure. And the second rotational flow generating device is arranged at the downstream of the first rotational flow generating device and is used for generating rotational flow for the air-powder mixture output by the medicine box.

Specifically, as shown in fig. 20 and 21, the second swirling structure 19 of the present embodiment includes a swirling passage and a swirling vane provided in the swirling passage. And the swirl vanes are fixedly arranged relative to the swirl passage. The arrangement is favorable for maintaining the stability of the amount of the medicinal powder inhaled each time.

The inhalation administration combination structure of the embodiment comprises a medicine box and an inhalation administration device. The inhalation drug delivery device is communicated with the wind powder outlet of the drug box to suck the drug powder in the drug box.

The structure of the inhalation delivery device of the present embodiment is described in detail below.

In the present embodiment, the inhalation delivery device includes a mouthpiece 16. The mouthpiece 16 has an air-powder suction passage communicating with the air-powder outlet of the medicine cartridge. The second cyclone structure 19 is disposed in the dust suction passage.

The inhalation drug delivery device of the present embodiment includes a vent port for introducing outside air, a drug cartridge housing chamber for housing a drug cartridge, and an air-powder suction port for sucking the drug powder in the drug powder containing chamber of the drug cartridge.

The inhalation delivery device of this embodiment comprises a housing for housing a cartridge. The shell is provided with the vent hole for introducing external air and a medicine box placing cavity for placing the medicine box.

Specifically, as shown in fig. 1, 2, 17, and 18, the housing of the present embodiment includes a first housing 1 and a second housing 2. The first casing 1 is provided with a vent 1A for introducing outside air. The second housing 2 has a cartridge placing chamber. The cartridge placing chamber has a first cartridge placing chamber opening 2A communicating with the vent 1A. The first medicine cartridge placing chamber opening 2A communicates with an air inlet 3A of the case body of the medicine cartridge to introduce outside air into the case body 3. The cartridge placing chamber of this embodiment also has a second cartridge placing chamber opening that communicates with the wind powder suction port. The patient sucks the medicine powder from the wind powder outlet through the wind powder suction passage of the mouthpiece 16.

Preferably, in order to filter the air entering the housing, as shown in fig. 17, the first housing 1 of the present embodiment is provided with a filter structure at the vent 1A. And the first medicine box placing cavity opening 2A of the second shell of the embodiment is provided with a flow equalizing structure.

Specifically, the mouthpiece 16 of the present embodiment includes a mouthpiece body 161 and a mouth containing portion 162 for mounting the mouthpiece 16 on the housing. The mouth inlet portion 162 is provided with the above-mentioned wind powder suction port 16A to provide suction force for the inhalation of the drug powder. When the patient uses the inhalation/drug delivery combination structure of this embodiment, the drug powder can be sucked into the body by holding the mouth containing portion 162 in the inlet and forcibly inhaling.

Since the mouthpiece 16 needs to be in direct contact with the mouth of the patient, in order to prevent contamination of the mouthpiece 16, the inhalation drug delivery device of the present embodiment further includes a mouthpiece cover 18 disposed outside the mouthpiece 16.

Preferably, the mouth containing part 162 of the present embodiment further has a peripheral wind suction port 16B provided at a side of the wind powder suction port 16A and communicating with the outside air to form a peripheral wind outside the wind powder suction port 16A. The peripheral air suction port 16B is arranged to form peripheral air outside the air powder suction port 16A, so that when the medicinal powder passes through the oral cavity, the peripheral air outside the main flow passage of the medicinal powder has a certain isolation effect on the medicinal powder, so that the medicinal powder is difficult to adhere to the wall of the oral cavity, and the proportion of the medicinal powder entering the lung for administration is increased.

In the present embodiment, a gas containing space is formed between the first casing 1 and the second casing 2. The gas entering the first housing 1 through the vent 1A of the first housing 1 partially enters the cartridge through the first cartridge placing chamber opening on the second housing, and partially enters the gas accommodating space formed between the first housing 1 and the second housing 2. The suction nozzle 16 is provided on the housing. And the air and powder suction port 16A of the suction nozzle 16 communicates with the second medicine box placing chamber opening on the second casing through the air and powder suction passage to suck the medicine powder. A peripheral wind suction port 16B of the suction nozzle 16 on one side of the wind powder suction port communicates with the gas containing space to communicate with the outside air to form a peripheral wind.

Specifically, as shown in fig. 17 and 18, the filter structure of the first casing 1 is provided with a support portion 1B extending toward the inside of the first casing 1. When the second housing 2 is fastened to the first housing 1, the support portion 1B provides a gap between the second housing 2 and the first housing 1, so that a gas accommodating space is formed between the outer side surface of the medicine box accommodating chamber of the second housing 2 and the first housing 1. When the suction nozzle 16 is mounted on the housing, the peripheral wind suction port of the suction nozzle 16 can suck the gas in the gas containing space to form peripheral wind.

Preferably, the mouth containing portion 162 is provided with at least two peripheral air suction ports 16B located at different positions in the circumferential direction of the air powder suction port 16A. So set up the air-out point that can increase the wind of periphery, prevent on the powder adhesion mouth cavity wall better.

In order to equalize the peripheral air outside the air and powder suction opening 16A and prevent the powder from greatly deviating in the flowing direction of the powder entering the inlet cavity, two peripheral air suction openings 16B are symmetrically arranged on two sides of the air and powder suction opening 16A of the present embodiment.

In an embodiment not shown in the drawings, at least two peripheral air suction openings may also be provided around the air dust suction opening. So set up and all form week wind in the week of making wind powder suction channel, prevent powder adhesion on the oral cavity wall more all-roundly.

The mouth inlet 162 includes a suction end surface located on one side of the mouth when suctioning. The wind powder suction port 16A and the peripheral wind suction port 16B are both provided on the suction end face.

Preferably, the suction end face of the present embodiment includes a curved surface that protrudes to the side away from the oral cavity. The curved surface forms a concave space so that the oral cavity containing part can be effectively attached to the oral lip to prevent the oral cavity from being exposed and avoid the tongue as much as possible, and the medicinal powder is prevented from being adhered to the oral cavity and the tongue.

Specifically, in this embodiment, the curved surface is an arc-shaped cylindrical surface.

In order to prevent the flow direction of the powder entering the oral cavity from the air powder suction passage from deviating, the oral cavity containing part of the embodiment includes two peripheral air suction ports located at both ends of the air powder suction port, and the centers of the two peripheral air suction ports and the center of the air powder suction port are located on the same straight line parallel to the generatrix of the arc-shaped cylindrical surface.

Preferably, in order to better atomize the powder, as shown in fig. 20 and 21, the inhalation delivery device of the present embodiment further includes a second cyclone structure 19 provided on the air-powder suction passage. Second whirl structure 19 makes the wind powder mixture of wind powder export produce the whirl and then further atomize when passing through wind powder suction channel to improve the atomization effect of powder, further improve the absorption rate of patient to powder.

The inhalation administration combination structure of the present embodiment atomizes the powder sufficiently to improve the absorption rate of the powder by providing the first cyclone structure 5 for generating a cyclone to the air flow before the powder is impacted and the second cyclone structure 19 for generating a cyclone to the air-powder mixture.

The suction nozzle 16 of the present embodiment further includes an air tube 15 provided between the nozzle body 161 and the housing. The air tube 15 is connected to the housing by an air tube connection 17. The inner cavity of the air tube 15 forms part of the air and powder suction passage.

Preferably, a rectifying structure 151 for rectifying the wind-powder mixture is arranged in the air pipe 15.

In the present embodiment, the second swirling structure 19 is disposed downstream of the rectifying structure 151, that is, the rectifying structure 151 is disposed between the first swirling structure 5 and the second swirling structure 19. Thus, the air flow generates rotational flow before the medicine powder is blown and then is mixed with the medicine powder to form the air-powder mixture. Carry out the rectification earlier through rectification structure 151 after forming wind powder mixture and make wind powder mixture steady flow in whole wind powder suction channel, then rethread second whirl structure 19 carries out the whirl to the wind powder mixture in whole wind powder suction channel, can make more wind powder mixtures carry out the whirl, makes the powder fully atomize.

Preferably, in order to accelerate the powder blown out from the medicine cartridge, the inhalation delivery device of the present embodiment further comprises an air-powder acceleration channel disposed between the first and second swirling structures 5 and 19. The air-powder accelerating channel enables the medicinal powder to be sufficiently accelerated under the driving of the air flow, so that the medicinal powder enters the second rotational flow structure at a high speed to be sufficiently atomized by effectively scattering the medicinal powder.

Specifically, in the present embodiment, the wind powder accelerating passage is an accelerating cavity disposed between the first swirling structure 5 and the second swirling structure 19. The acceleration chamber provides a space for acceleration of the powder, so that the powder can have a faster speed when entering the second cyclone structure.

Preferably, the length of the acceleration chamber is greater than or equal to 10 mm.

More preferably, the length of the acceleration chamber is greater than 20 mm.

In order to improve the convenience of the patient in using the inhalation delivery combined structure of the present embodiment, the inhalation delivery device of the present embodiment includes a driving mechanism for driving the movement of the drug powder containing body relative to the case body 3.

In this embodiment, the drive mechanism comprises a ratchet disc 9 which is rotatable relative to the cassette 3. The ratchet disc 9 is provided with ratchet disc pawls 91. The medicine powder containing body is provided with a containing body ratchet. The ratchet disc pawls 91 drive the containing body ratchet to rotate to drive the powder containing body to rotate.

Specifically, as shown in fig. 5, the second containing division 6 of the medicine powder containing body is provided with a containing body ratchet 61 on the top surface thereof. The ratchet plate 9 on which the ratchet plate pawls 91 are mounted is mounted on the mounting plate 7 and cooperates with the containing body ratchet provided on the medicine powder containing body to drive the second containing division 6 to rotate. The second accommodation division body 6 is connected to the first accommodation division body 4, so that the first accommodation division body 4 can also be rotated in synchronization with the second accommodation division body 6 to thereby achieve rotation of the medicine powder accommodation body.

As shown in fig. 13, the mounting plate 7 is provided with a plurality of connection bars 71 arranged at intervals in the circumferential direction. The ratchet disc 9 is provided with a plurality of coupling projections 92. The connecting strip 71 is snapped between the two connecting projections 92 to mount the ratchet disc on the mounting plate 7.

For convenience of operation, as shown in fig. 9, the inhalation-drug delivery combination structure in the present embodiment further includes a dial 13 provided with a knob. Ratchet disc 9 is connected to rotary disc 13 for synchronous rotation by rotary disc 13.

Turntable 13 is provided with a turntable pawl 131. Of course, in an embodiment not shown in the drawings, the drug powder container may be driven to rotate by directly engaging the ratchet of the dial with the ratchet of the container.

In order to facilitate obtaining the usage information of the medicine cartridge of the present embodiment, the inhalation drug delivery device of the present embodiment further includes an information display structure for displaying the usage information of the medicine cartridge.

The medicine powder containing body comprises more than two medicine powder containing cavities. The information display structure comprises more than two marker discs 8 with more than two marks corresponding to the more than two medicine powder containing cavities. The marker disk 8 rotates in synchronism with the powder containing body. As shown in fig. 15 and 16, the inhalation-administration combination structure of the present embodiment includes a dial 8 and a dial outer 10. The turntable outer ring 10 is fixedly arranged relative to the case 3. The turntable outer ring 10 is provided with a window 10A. The marker disk 8 is arranged below the turntable outer ring 10. The window 10A may display the logo on the logo plate 8 during rotation of the logo plate 8. Also, as shown in fig. 1, the turntable 13 is disposed at the middle of the turntable outer ring 10, and an arrow is disposed on the turntable outer ring 10 to show the direction of rotation of the turntable 13.

Specifically, in this embodiment, as shown in fig. 16, the marker plate 8 is provided with counting marks corresponding to two or more powder holding chambers. The dial 8 is rotated synchronously with respect to the powder medicine accommodating body to display the use condition of the powder medicines in the plural powder medicine accommodating chambers in the powder medicine accommodating body. For example, with the medicine cartridge of the present embodiment, there are seven medicine powder containing chambers. When the cartridge of this embodiment is not in use, the dial 8 count flag is displayed as zero. The counting marks of the marking disk 8 become larger gradually as the medicine powder in the medicine powder containing cavity in the medicine box is used gradually. When the counting mark on the marking disc 8 reaches seven, the patient can know that the medicine powder in the medicine box is completely used up, and the medicine box can be replaced by a new medicine box for use. The provision of the marker disk 8 makes the inhalation administration combination of the present embodiment more convenient to use.

In other embodiments, the mark on the marking plate may further include information on the use of the medicine cartridge, such as information on the kind of the medicine powder. For example, when two or more powder medicine-containing chambers contain different kinds of powder medicine, the marker on the marker plate may be powder medicine kind information corresponding to the kinds of powder medicine in the powder medicine-containing chambers.

In order to rotate the dial 8 in synchronization with the powder container, as shown in fig. 16, a dial ratchet is provided on the inner edge of the dial 8. The turntable pawls 131 cooperate with the marker disc ratchets to drive the marker disc ratchets to rotate, and at the same time, the turntable drives the pawl disc 9 to rotate synchronously, thereby making the marker disc 8 and the medicine powder containing body rotate synchronously, so that the counting marks on the marker disc 8 can show the use state of the medicine powder containing cavity of the medicine powder containing body.

Preferably, as shown in fig. 11, the inhalation-delivery combination structure further comprises an elastic member 12 for automatically returning the ratchet of the rotating disc, a first end of the elastic member 12 is fixedly disposed opposite to the rotating disc 13, and a second end of the elastic member is fixedly disposed opposite to the box body 3.

Specifically, as shown in fig. 10, the bottom of the rotating disk 13 is provided with a first coupling groove 13A, and a first end of the elastic member 12 is coupled in the first coupling groove 13A. The inhalation and administration combination structure of the embodiment further comprises a limiting disc 11 which is fixedly arranged relative to the box body 3. The limiting disc 11 is provided with a second connecting groove 11B. A second end of the elastic member 12 is coupled to the second coupling groove 11B. Because the first end of elastic element 12 is fixedly connected with carousel 13, the second end of elastic element 12 is fixedly connected with spacing dish 11, consequently can be automatic the return under the pulling of elastic element 12 after carousel 13 rotates under patient's rotation.

In the present embodiment, the elastic member 12 is a torsion spring.

Preferably, in order to control the rotation range of the ratchet 131 of the rotary disc so that the plurality of powder containing cavities are sequentially communicated with the air powder outlet on the box body 3, and thus sequential administration of the powder in the plurality of powder containing cavities by the patient is realized, as shown in fig. 14, a limiting groove 11A is provided on the limiting disc 11 of this embodiment. As shown in fig. 10, the rotary plate 13 is provided with a limit protrusion 132. The limit projection 132 swings in the limit groove 11A to limit the range of rotation of the turntable pawl 131 at a time.

More preferably, in order to ensure the reliability of the limit of the turntable pawl 131, the limit disk of the present embodiment is provided with two limit grooves which are symmetrically arranged. The two limit grooves are respectively matched with the limit bulges on the rotating disc 13.

The driving mechanism of the embodiment realizes the display of the use state of the medicinal powder containing body by the marking disc 8 by arranging the rotary disc 13 and the pawl disc 9 which synchronously rotates with the rotary disc 13, so that the rotary disc 13 drives the marking disc 8 to rotate while the rotary disc pawls on the rotary disc 13 drive the marking disc 8 to rotate. And the rotary disk 13 is provided with a knob, which is convenient for the operation of the patient.

The test results of the test personnel using the first preparation and the second preparation to respectively test the powder suction effect of the medicine box provided with the first rotational flow structure and the powder suction effect of the medicine box not provided with the first rotational flow structure are shown in table 1. The first preparation has a particle diameter of 10 μm. The second preparation has a particle diameter of 2.8 μm. As shown in the test data in table 1, for two reagents having different diameters of powder particles, the powder suction amount of the cartridge provided with the first cyclone structure is larger than that of the cartridge not provided with the first cyclone structure in the same loading amount. In summary, the first rotational flow structure can increase the amount of the powder sucked out of the medicine box.

Table 1: test result of medicine box with first rotational flow structure

The test personnel respectively tested the powder suction effect of the medicine boxes provided with the first and second cyclone structures and the powder suction effect of the medicine boxes provided with the first cyclone structure but not provided with the second cyclone structure by using the third and fourth preparations, and the test results are shown in table 2. In table 2, gmd (geometric Mean diameter) represents the geometric Mean diameter of the powder particles, and mmad (mass media Aerodynamic diameter) represents the mass Mean Aerodynamic diameter of the powder particles. Wherein the geometric mean diameter of the particles of the drug powder of the third preparation is 2.1 μm. The geometric mean diameter of the drug powder particles of the fourth preparation was 2 μm.

As shown in the test data in table 2, the mass mean aerodynamic diameter of the powder sucked out by the cartridge with the second swirling structure is smaller than that of the powder sucked out by the cartridge without the second swirling structure. And the proportion of the powder with the mass average aerodynamic diameter smaller than 3.4 mu m and smaller than 5 mu m in the powder sucked out by the medicine box provided with the second rotational flow structure is larger than the proportion of the corresponding mass average aerodynamic diameter in the powder sucked out by the medicine box not provided with the second rotational flow structure. In conclusion, the arrangement of the second rotational flow structure can fully atomize the medicinal powder, and is more beneficial to the absorption of patients.

Table 2: test result of medicine box provided with first rotational flow structure and second rotational flow structure

In summary, the rotational flow generating device and the medicine box of the embodiment of the invention have at least the following advantages:

according to the rotational flow structure provided by the embodiment of the invention, more than two rotational flow parts which are arranged in a surrounding manner are arranged in the rotational flow channel, so that airflow at different positions between the radial inner side of the flow channel and the radial outer side of the flow channel of the rotational flow channel can generate rotational flow, the airflow at different positions in the whole flow channel can generate rotational flow, the suction effect on the medicinal powder is improved, and the proportion of the medicinal powder sucked into the lung is increased.

The medicine box provided by the embodiment of the invention is internally provided with the first rotational flow structure, so that the suction quantity of the medicine powder can be increased. The second rotational flow structure is arranged to improve the atomization effect of the medicine powder, so that the medicine powder amount inhaled into the lung of a patient is improved.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention and not to limit it; although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art will understand that: modifications to the specific embodiments of the invention or equivalent substitutions for parts of the technical features may be made; without departing from the spirit of the present invention, it is intended to cover all aspects of the invention as defined by the appended claims.

Claims (11)

1. A medicine box for inhalation administration is characterized by comprising a medicine powder containing cavity for containing medicine powder and a rotational flow generating device, the rotational flow generating device comprises a rotational flow structure, the rotational flow structure is provided with an airflow inlet end, an airflow outlet end and a rotational flow channel arranged between the airflow inlet end and the airflow outlet end, the swirl passage comprises more than two swirl parts which are arranged from the center of the flow passage to the edge of the flow passage along the radial direction, each swirl part is arranged around along the circumferential direction and is used for generating swirl on part of airflow input into the swirl passage and then outputting the swirl, the powder-containing chamber has a first opening for introducing an air flow for transporting the powder and a second opening for discharging an air-powder mixture, the rotational flow generating means is disposed upstream of the first opening of the powder-containing chamber so that the air flow generates a rotational flow before the powder is delivered and delivers the powder in a rotational flow state and mixes with the powder to form an air-powder mixture.

2. The kit for inhalation delivery according to claim 1, wherein said swirl portion comprises at least one swirl vane.

3. The kit for inhalation delivery according to claim 2, wherein each of said swirl vanes is fixedly disposed.

4. A cartridge for inhalation delivery according to any one of claims 1 to 3, wherein said swirling flow generating means further comprises an outer flow guide surface provided outside the first swirling portion from the edge of the flow path.

5. The kit for inhalation delivery according to claim 4, wherein said outer baffle surface is a diverging surface having a cross-sectional area gradually increasing from upstream to downstream of said swirl passage at least on the side of said air flow outlet end.

6. The cartridge for inhalation delivery according to any one of claims 1 to 3, wherein a partition structure for partitioning the airflows of the two cyclone parts is provided between the adjacent cyclone parts.

7. The kit for inhalation delivery according to claim 6, wherein the partition structure comprises a first intermediate flow guide surface for guiding the flow of the swirl portion near the center of the two swirl portions partitioned by the partition structure and/or a second intermediate flow guide surface for guiding the flow of the swirl portion near the edge of the two swirl portions partitioned by the partition structure.

8. The cartridge for inhalation delivery according to claim 7, wherein said first intermediate baffle surface is a divergent surface having a sectional area gradually increasing from upstream to downstream of said swirl passage at least on the side of the air flow outlet end; and/or the second middle diversion surface is an expansion surface at least on one side of the airflow outlet end, and the cross-sectional area of the expansion surface is gradually increased from the upstream to the downstream of the rotational flow channel.

9. The cartridge for inhalation delivery according to claim 1, further comprising another swirling flow generating means for swirling said air-powder mixture, disposed downstream of said second opening of said powder-holding chamber.

10. An inhalation combination comprising an inhalation device and a cartridge arranged to cooperate with the inhalation device, wherein the cartridge is a cartridge according to any one of claims 1 to 9 for inhalation administration.

11. The inhalation-drug delivery combination according to claim 10, comprising another swirl generating device disposed downstream of the swirl generating device to generate a swirl to the air-powder mixture output from the drug cassette.

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