DE2023891C3 - Inhalation device for finely divided medication - Google Patents

Description

where the expression

R-r

is at least the amount greater than the expression Rc which is at least required to transfer the medicament in the capsule (5) into a flowing fluidized or in suspension medium when the inhalation device is put into operation by passing a gas through, where further ρ smaller

as - is and 2R is one between

100

2 / -

100

2.5 h
100

lying size and where denote:

a = distance (a) of the base or a point of the base circle of the wall parts (or the circumference of the bottom) of the cylindrical capsule (5), which are parallel in the axial longitudinal section, from the non-dominant point of contact between the shaft (2) and the bearing tube (3), when the capsule (5) is in its working position in the receiving device (4);

Λ = distance (h) between the dominant and the non-dominant point of contact between the shaft (2) and the bearing tube (3);

R = inner radius (R) of the bearing tube (3) at the dominant point of contact between the shaft (2) and the bearing tube (3);

r = radius of the shaft (2);

R _c = inner radius (R ₀ ) of the capsule (5) at a distance a from the non-dominant contact point between the shaft (2) and the bearing tube (3), and

ρ = inner radius (ρ) of the narrower end of the bearing tube (3) at the point of contact this end with the shaft (2).

2. Apparatus according to claim 1, characterized in that the number of by the not dominant motion components caused nodes exceeds the number 15

3. Device according to claims 1 or 2, characterized in that the angle of the precession cone or the truncated precession cone, within which the axis of the bearing tube (3) describes a path between 0.5 and 30 °

4. Apparatus according to claim 3, characterized in that the precession cone angle is ^{between 0.5 and 5 e}

5. Apparatus according to claim 1, characterized in that one on the capsule (5) is provided Shoulder has at least two holes through the capsule, and the capsule in the Cup of the receiving device (4) is inserted so that the perforated end is the free end

²⁰ State of the art

The subject of claim 1 of the main patent 14 91715 is an inhalation device for finely divided Medicines with an elongated housing, each with one or more air passages to the Ends, one of which is equipped for insertion into the mouth, one with in the housing Propeller-like lugs provided receiving device for the medicament rotatable on a central Shaft is mounted, the receiving device as a holder for a closed and with perforations provided capsule is designed for the medicament and is mounted with play on the shaft that a vibration is superimposed on their rotary motion

From the previously published patent specification of this main patent, it is also known that a as Bearing tube formed bearing is firmly connected to the receiving device and for mounting a rigid into the bearing tube protruding cylindrical part of the shaft serves the other end in a part of the Housing sits coaxially in this, the diameter of the bore of the bearing tube tapers and is larger at the outer end than at the inner end. With regard to the storage of the receiving device there stated that the bearing for the shaft forming the bore of the receiving device on the inner The end has an inner diameter of 1.5 to 6%

^r M is greater than the diameter of the shaft, and that the bearing at the outer end has an inner diameter which is greater than the diameter of the shaft by 1.3 to 3.5% of the total length of the bearing. Or the bearing has an inner passage at the inner end

T) knife, which is about 3.75% larger than the Diameter of the shaft, and the bearing has at the outer end an inner diameter that is about 2.5% of the length of the bearing is greater than the diameter of the shaft, the length of the bearing

bo the cradle four to ten times as large as the diameter of the shaft can be. In all of these cases the bore of the bearing tube is at the inner end a smaller diameter than at the outer end. The fluidization of the finely divided drug and thus

μ also the uniformity of the delivery of this drug however, air passage through the known inhalation device is not always satisfactory.

task

The invention specified in claim 1 has the object of providing an inhalation device for To propose finely divided drugs that are well fluidized and in their actuation uniform and complete delivery of the finely divided medication

advantages

If these conditions are met, the bearing tube rotating around its own axis also makes one Precession movement around the axis of the shaft, the axis of rotation of the bearing tube describing a path that lies within a precession cone or truncated cone and improves fluidization and atomization of the drug enters The dimensions of this precession cone or truncated cone depend on it from the radius of the shaft and the radii on the inside of the bearing tube at each of its ends as well on the length of the bearing tube, and they depend on each other according to the inequality of the Claim 1 from each other. This inequality has a solution with many permutations, i.e. different solution values for the dimensions of the device. The invention therefore allows one Variety of dimensions of the device.

The total movement of a point on the wall of the capsule in a plane radial to the axis of precession can be described as epitrochoidal movement. This epitrochoidal movement is a trajectory with a circular arc-shaped sequence of inflection points that merge into one another at nodal points, the Transition curves, simple points or small loops can be a turning point of the curve connect with the next. While the capsule sitting on the bearing tube rotates and a precession movement executes, every point on the capsule wall experiences several changes in its radial acceleration during one revolution of the capsule at a time. If those from the axis of the precession cone respectively - The truncated cone acceleration on the capsule wall is sufficiently large, so the Overcome the forces that hold the powder particles to the wall. The powder then separates from the wall and moves in free flight in the capsule, while its wall continues its trochoidal path. The particles later hit the wall again at a different point. Because the axis of rotation of the capsule with the Precession axis forms an angle, it is to be assumed that the particles hit the wall then at a point impinge, which is offset in the direction of the capsule axis, so the particles are not only within the Capsule kept suspended, but also moved in the axial direction.

During the rotation and precession there is a progressive movement at both ends of the bearing tube Contact, preferably a rolling contact, takes place between the bearing tube and the shaft. Everyone Contact creates a trochoidal component of motion, and these components of motion are superimposed and thus generate a resulting overall movement of the capsule wall. In the course of the one Movement generated at the end of the bearing tube moves a point on the capsule wall during each revolution of the capsule around the axis of precession through a number of nodes of the trochoidal orbit. The number of The knot depends on the dimensions of the bearing and the shaft at the point of contact. at Rolling contact, the number of nodes is one less than the ratio of the speed of the initial movement of the Capsule around the axis of precession to the speed of the capsule when it rotates around its own axis; this ratio is called the frequency ratio in the following. This frequency ratio depends in turn, on the ratio of the inner diameter of the bearing at the point of contact to the total distance of the

to shaft from the bearing surface of the bearing tube on this Point off. The larger this distance, the more eccentric and, as a rule, the more dominant it is also the trochoidal movement component produced by this touch.

In the inequality of claim 1, the minimum requirements for bringing about the fluidization are of the powder particles given under the specified conditions. However, there still have to be the forces acting between the particles are overcome. Also can not be dominant Movement component counteracting the dominant movement component in whole or in part and reduce the fluidization generating forces.

The left-hand side of the inequality must therefore exceed the right-hand side by an amount equal to that of the Centrifugal and cohesive forces between the particles depends

The subclaims describe advantageous developments of the invention, namely measures with which a particularly good fluidization of the particles is effected.

Presentation of the invention

The invention is explained in more detail below with reference to schematic drawings

F i g. 1 is a longitudinal section through a first embodiment of a novel inhalation device;
Fig. 2 is a longitudinal section through a second embodiment of the novel inhalation device;

F i g. 3 is a longitudinal section through a joint with the device according to FIG. 2 usable caps.
The in F i g. The device shown in FIG. 1 has a tubular housing 1, one end B of which can be inserted into the mouth. Coaxial with the housing 1 is a cylindrical shaft which loosely and rotatably carries an elongated bearing tube 3 with wings 4. The bearing tube also has a cup-like receptacle in which a perforated capsule 5 holds the finely divided drug (powder).

If the end B of the housing 1 is inserted into the mouth and air is inhaled, the air flow resulting therefrom causes the bearing tube 3 to rotate and precess, so that the finely powdered, powdered medicament in the capsule 5 exits the capsule and in the air flow on the wings 4 past the end fl leaves the housing 1 and from there into the mouth and the respiratory organs of the user

bo enters.

The in F i g. 2 has a housing with an approximately circular cross-section a diameter of about 1.9 cm and a large of about 5 cm. She owns two

b5 overlapping housing parts 6 and 7, the housing part 7 can be inserted into the mouth. This housing part 7 also has openings 8 for air flowing through. With the housing part 7 and

A shaft 2 made of cold-drawn stainless steel wire is arranged coaxially with it, which in turn is under Play and rotatably carries an elongated bearing tube 3 made of hard polyamide. This bearing tube wears a Propeller part with blades 4.

The propeller part also has a cup-shaped part which has a capsule 5 receives finely powdered drug in a press fit. The cup part has, for example, one for receiving a capsule with an inner diameter of 6.3 mm suitable size, the capsule with the base of its cylindrical wall about 0.51 cm from the outer end of the bearing tube.

The diameter on the inside of the bearing tube 3 is about 2.67 mm and the diameter at the outer end of the bearing tube is about 3.05 mm. That Bearing tube 3 has an inner length of approximately 12.7 mm and the shaft 2 has a diameter of approximately 2.64 mm. In this embodiment of the device, the dominant movement component is generated by the outer end of the bearing tube

The end 17 of the shaft 2 is conical, with a cone angle of about 30 °. the Shaft terminates in a substantially hemispherical tip 18 with a diameter about half that Corresponds to the diameter of the shaft 2.

The housing part 6 has openings 9 for the inflowing air at one end. Furthermore is on This housing part is provided with a constriction member 10 through which the introduced air flow is constricted. This will reduce the gas velocity in Direction of flow behind the capsule increased

A closing part 11 extends through the bottom wall of the housing part 6, with which a closing part 11 extends on the outside Bottom part 12 is connected. Between this bottom part and the housing part 6 there is a spring 13 which pushes the locking member 11 into a normally open position. The bottom member 12 has a threaded portion 14, which engages in a similarly designed threaded section 16 of a cap 15 (compare Fig. 3), so that the locking part 11 is kept closed. At the same time, the capsule 5 is thereby in the shape of a cap Receiving part of the propeller part held. If the cap 15 is in its working position, then no air can inhaled through the device and the capsule 5 held in place. If the cap 15 is removed, so The spring 13 urges the closure member 11 to its normally open position, allowing air to pass through the device can be sucked in. Here, the propeller part rotates with the blades 4 and the bearing tube 3 and the powdered drug in the capsule 5 is atomized

Around the closing part there is a disk 19 which serves as a one-way valve for the device. If air is blown through the device, the disk is moved against the bottom wall of the housing part 6 so that the openings 9 are closed. With this flow direction (opposite to the arrow direction at A and B in Fig. 1), no air can flow in this direction a If air is sucked through the device (in Direction of the arrow at A or B, Fig. 1), the disk 19 lifts off the bottom wall of the housing part 6, whereby the openings 9 are exposed. Air can therefore flow through the device.

In another embodiment, the bearing tube has the following dimensions: diameter at the Inside 2.06 mm; Diameter on the outside 2.36 mm; Inner length 12.7 mm and diameter of the 2.03 mm shank.

ι ο devices, such as two examples of the main patent, in which a stationary, rigid cylindrical shaft is mounted in a rotatable bearing tube whose Inner diameter 2 ρ at its inner end is 1.5 to 6.0% larger than the shaft diameter, and that at its outer end has an inner diameter, which is 1.3 to 2.5% of the length of the bearing greater than the diameter of the shaft do not belong to the

Subject of the invention. That is to say, according to the invention, he has as in front of him

Inner radius at the narrower end of the bearing tube at the point of contact between the shaft and the bearing tube defined radius a size less than is,

if 2R is an amount between

100

and

2 /

100

2.5 100

owns. In FIG. 2 of the drawings are the reference book members a, h, r, R, R _c and ρ are entered. The lines a and h relate in their arrangement to the aforementioned embodiment of the invention, in which the dominant movement component of the bearing tube is at its outer end and the one is not dominant component of the movement of the support tube in that height is in the inner end of the shaft 2 changes from its cylindrical portion into a conical tapered end portion In this embodiment, the distance a likewise ends in the last-mentioned amount, as in Fig. 2 is shown and how it applies to most embodiments

However, there are also embodiments if, for. B. Harmonic harmonics of the oscillating movement of the bearing tube occur, possible in which the non-dominant movement component of the bearing tube or the receiving device at the lower end of the bearing tube is present, while the dominant component of its movement then lies in the height, in which the cylindrical part of the shaft 2 at his inner end into a conically pointed part passes In this embodiment, route a ends (other than in Fig. 2 below) shown in the same

Height as the lower end of the storage tube. The length and position of the segment h remains in both Execution cases the same as in FIG. 2. For this purpose 3 sheets of drawings

Claims (1)

Patent claims: 1. Inhalation device for finely divided medicaments according to claim 1 of the main patent 1491715, characterized in that the receiving device is designed as a bearing tube (3) and for mounting a cylindrical part of the shaft (2) which protrudes rigidly into the bearing tube serves, the other end in the housing (1) is fixed coaxially that the diameter of the bore of the Bearing tube (3) for receiving the shaft (2) tapers and larger at the outer end than at the inner end is that the smallest inner diameter of the bore of the bearing tube (3) is greater than that Diameter of the shaft (2), and that the dimensions of the shaft (2), the bearing tube (3) and the receiving device connected to the propeller-like attachments satisfy the following inequality: