Title of Invention	"DEVICE FOR HOLDING A FLUIDIC COMPONENT"
Abstract	The mounting of a component subjected to pressure from a fluid requires special precautions if the component is made of wear resistant, hard and hence generally brittle material and may be destroyed by locally raised stresses. A fluidic component of this kind, (e.g. made of silicon/glass) is arranged in an elastomeric shaped component, e.g. made of silicon rubber, the contours of which correspond to the outer contours of the component and to the inner contours of a holder. Because of the "floating mounting" there are no unacceptable local pressure peaks and no deformation of the fluidic component. The device is particularly suitable for mounting a fluidic component made of glass or silicon, of miniature dimensions, subject to high pressure.

Title of Invention

"DEVICE FOR HOLDING A FLUIDIC COMPONENT"

Abstract

The mounting of a component subjected to pressure from a fluid requires special precautions if the component is made of wear resistant, hard and hence generally brittle material and may be destroyed by locally raised stresses. A fluidic component of this kind, (e.g. made of silicon/glass) is arranged in an elastomeric shaped component, e.g. made of silicon rubber, the contours of which correspond to the outer contours of the component and to the inner contours of a holder. Because of the "floating mounting" there are no unacceptable local pressure peaks and no deformation of the fluidic component. The device is particularly suitable for mounting a fluidic component made of glass or silicon, of miniature dimensions, subject to high pressure.

Full Text	The invention relates to a device for holding a fluidic component, particularly nozzles or jets, particularly at high pressures. Holders for microstructured components, particularly microstructured nozzles are of particular interest. The invention relates in particular to a device for holding a microstructured nozzle as used in nebulizers for producing propel1ant-free medicinal aerosols for inhalation. Nozzles of this kind are disclosed, for example, in WO 94/07607. A characteristic feature of these nozzles is that they generate inhalable droplets around 5 µm in size, the liquid which is to be nebulized being sprayed at high pressure (between 50 and 400 bar or more and optionally up to 600 bar) through a nozzle with an opening of less than 10 µm. Nozzles of this kind may be produced, for example, from thin silicon plates and glass plates and have external dimensions in the millimetre range. A typical nozzle consists, for example, of a box shape made up of two plates with edges measuring 1.1 x 1.5 x 2.0 mm in length. Nebulizers for producing propellant-free aerosols in which the devices for mounting a nozzle according to the invention may be used are known, for example, from WO 91/14468. The aim of the invention is to provide a device of this kind which is preferably suitable for a fluidic component of wear-resistant, hard and consequently usually brittle material. The term fluidic component refers to a component which is exposed to a pressurized fluid, whilst the pressure may also prevail inside the component, e.g. in a nozzle bore. A component of this kind may, for example, be mounted in pressure tight manner by pressing it into a holder of hard material, if the material of the component can withstand mechanical forces without breaking or being deformed to an unacceptable extent. For use at high pressures, seals of deformable material, e.g. copper, or hard materials are used, which can be compressed under considerable force. In the case of components made of brittle material, the known methods of mounting the component in pressure tight manner give rise to considerable expenditure and require great care. Only limited data can reliably be provided as to the service life of a fluidic component mounted in this way. The objective is therefore to provide a device for holding a fluidic component, which is also suitable for components made of wear-resistant, hard and consequently usually brittle material, and which does not exhibit any unacceptably high pressure points in the material of the component. This objective is achieved according to the invention by means of a device for holding a fluidic component which is subjected to a fluid pressure, characterised by a holder inside which the fluidic component is mounted, and which makes contact with the fluidic component at the low pressure end thereof, an elastomeric shaped component the outer contour of which corresponds to the inner contour of the holder and the inner contour of which corresponds to the outer contour of the fluidic component whilst the elastomeric shaped component surrounds the fluidic component around its entire perimeter, and the elastomeric shaped component has at least one free surface which is exposed to the pressurized fluid. The elastomeric shaped component is preferably produced by injection moulding, in which the pre-elastomer is transferred free from bubbles into a mould which corresponds to the contours of the holder and the fluidic component. The pre-elastomer hardens in the mould, preferably under pressure. The elastomeric component may also be produced at the place where it is intended to hold the fluid component. An elastomeric shaped component of this kind behaves somewhat like an incompressible fluid. It fits perfectly with the holder and the fluidic component. The elastomeric shaped component surrounds the fluidic component around its entire perimeter. The elastomeric shaped component is exposed to the fluid pressure only at the pressure end, not at the sides where it fits the holder and the fluidic component. The elastomeric component enables the pressure on the fluidic component to be equalised. The elastomeric component does not have any free surface at the low pressure end. The elastomeric component may consist, for example, of natural rubber or synthetic rubber such as silicon rubber or polyurethane. The fluidic component may consist of wear resistant, hard and hence generally brittle material (such as silicon, glass; ceramic, gemstones, e.g. sapphire, ruby, diamond, or a ductile material having a wear resistant hard surface (such as plastics, copper, hard chromium plated copper, brass, aluminium, steel, steel with a hardened surface)). It may be made in one piece or be assembled from a number of pieces, and these pieces may consist of different materials. The fluidic component can have cavities, recesses or channel structures, e.g. a nozzle structure. The holder may consist of virtually any desired material, preferably metal or plastics, and can be a rotational body or a body of any desired shape. It may be produced by moulding, casting or by machining. It may be advisable, e.g. in the case of a cylindrical elastomeric shaped component, to subject the elastomeric shaped component to a constant mechanical force which subjects the elastomeric shaped component to ft prestressing. This can be achieved by press fitting or by means of one (or more) displacement members which exert pressure onto or into the elastomeric shaped component. The apparatus according to the invention has the following advantages: No unacceptable local pressure peaks are produced in the fluidic component, since the "floating mount" ensures that the fluid pressure inside and outside the fluidic component is at virtually the same level. The forces exerted by the holder and the fluid pressure via the fitted elastomeric shaped component onto the fluidic component do not produce any deformation of the fluidic component. A fluidic component consisting of a material which is to some extent ductile can be clamped in just the same way as a fluidic component made of brittle material. The mounting of the fluidic component remains sealed even if the fluid pressure abates or a (slight) under pressure is formed. The mounting is not sensitive to dynamic high pressure loads, e.g. caused by pressure surges. The fluidic component and the elastomeric shaped component can easily be mounted in the holder without force and with no need for adjustment. For the fluidic component there is no risk of brittle fracture and for the elastomeric component there is no risk of it slipping out of the holder. It is particularly suitable for a fluidic component of miniature dimensions. The apparatus in accordance with the invention will be explained in more detail with reference to the drawings. Figure 1 shows the cylindrical holder 1 made of metal in an oblique view. It has a frustum-shaped recess 2, the diameter of which is somewhat greater at the high pressure end than at the low pressure end. In its base 3 the holder has an opening 4. The exterior of the holder may be frustum-shaped and the recess may be cylindrical. Figure 2 shows the elastomeric shaped component 5, the shape of which corresponds to the shape of the holder according to Figure 1 and to the shape of the fluidic component according to Figure 3. Figure 3 shows a fluidic component 6 consisting of two rectangular plates joined together at their contact surface. At least one of the plates is provided with a channel structure 7 which contains a nozzle on the low pressure side. Figures 4a and 4b each show a cross-section through another embodiment of the apparatus, each in a plane lying along the axis of the device and in each case parallel to one side of the fluidic component. The holder 8 is provided with a ring 9 which projects beyond the edge of the elastomeric component. Figure 5 shows a microstructured fluidic component in the form of a nozzle arrangement 10, comprising a base plate 11 and a cover plate 12. To make the drawing clearer, the two plates are shown separately. In the finished state, the two plates are fixed together, so that the fluid which is to be nebulized penetrates through the filter arrangement 13 on the inlet side 16 (high pressure side) into the nozzle arrangement 10 and through the narrow channels 17 and the two wider channels 15 to the nozzle outlet 14 (low pressure side). The plates 11 and 12 may be made of silicon or glass. Other details of the nozzle are disclosed in WO94/07607, to which reference is made herein. EXAMPLE; Mounting for a Nebulizer Nozzle of Miniature Construction This device consists of a cylindrical holder made of steel with an external diameter of 3.2 mm and a height of 2.6 mm. It contains a recess with an internal diameter of 2.3 mm at the high pressure end and 2.1 mm at the low pressure end. The base of the holder is 0.4 mm thick and contains a bore 0.8 mm in diameter. The elastomeric shaped component made of silicon rubber is a frustum. Before it is inserted in the holder it has a diameter of 2.3 mm at the high pressure end and 2.2 mm at the low pressure end and is 1.8 mm high. It contains a recess, symmetrical with its axis, extending along its full height, with a width of 1.0 mm and a length of 1.4 mm. The fluidic component is a box shape made up of two silicon plates, which is 1.1 mm wide, 1.5 mm long and 2.0 mm high. In the contact surface between the plates it contains a flat, triangular recess 400 µm thick, which terminates in a channel 50 µm wide, 50 µm thick and 200 µm long. The device is fixed to a container which contains the fluid to be nebulized. The pressure of the fluid inside the fluidic component is 32 MPa (320 bar). Claims 1. Device for holding a fluidic component which is exposed to fluid pressure, characterised by a holder inside which the fluidic component is mounted, and which makes contact with the fluidic component at the low pressure end thereof, an elastomeric shaped component the outer contour of which corresponds to the inner contour of the holder and the inner contour of which corresponds to the outer contour of the fluidic component whilst the elastomeric shaped component surrounds the fluidic component around its entire perimeter, and the elastomeric shaped component has at least one free surface which is exposed to the pressurized fluid. 2. Device according to claim 1 characterised by a fluidic component made of wear resistant, hard and consequently usually brittle material (such as silicon, glass, ceramic, gemstone) or ductile material (such as plastics or metal, preferably copper, hard chromium plated copper, brass, aluminium, steel, steel with a hardened surface) or a combination of these materials. 3. Device according to claim 1 and 2, characterised by a fluid component which is in one piece or made up of a plurality of pieces. 4. Device according to claims 1 to 3, characterised by an elastomeric shaped component made of natural rubber or synthetic rubber such as silicon rubber or polyurethane. 5. Device according to claims 1 to 4, characterised by a microstructured fluidic component of silicon, glass or silicon/glass having a channel structure. 6. Device according to claims 1 to 5, characterised by a displacement member which compresses the elastomeric shaped component. 7. Device according to one of claims 1 to 6, characterised by a fluidic component in the form of a nozzle for nebulizing medicinal solutions for inhalation. 8. Use of a device for holding a fluidic component according to one of claims 1 to 7 in a nebulizer for producing propellant-free aerosols for inhalation. 9. Use of a device for holding a fluidic component according to one of claims 1 to 7, in which a pressure of up to 600 bar prevails at the high pressure end. 10. Device for holding a fluidic component substantially as hereinbefore described with reference to and as illustrated in the accompanying drawings.

Full Text

The invention relates to a device for holding a fluidic component, particularly nozzles or jets, particularly at high pressures. Holders for microstructured components, particularly microstructured nozzles are of particular interest.
The invention relates in particular to a device for holding a microstructured nozzle as used in nebulizers for producing propel1ant-free medicinal aerosols for inhalation. Nozzles of this kind are disclosed, for example, in WO 94/07607. A characteristic feature of these nozzles is that they generate inhalable droplets around 5 µm in size, the liquid which is to be nebulized being sprayed at high pressure (between 50 and 400 bar or more and optionally up to 600 bar) through a nozzle with an opening of less than 10 µm. Nozzles of this kind may be produced, for example, from thin silicon plates and glass plates and have external dimensions in the millimetre range. A typical nozzle consists, for example, of a box shape made up of two plates with edges measuring 1.1 x 1.5 x 2.0 mm in length. Nebulizers for producing propellant-free aerosols in which the devices for mounting a nozzle according to the invention may be used are known, for example, from WO 91/14468.
The aim of the invention is to provide a device of this kind which is preferably suitable for a fluidic component of wear-resistant, hard and consequently usually brittle material.
The term fluidic component refers to a component which is exposed to a pressurized fluid, whilst the pressure may also prevail inside the component, e.g. in a nozzle bore. A component of this kind may, for example, be mounted in pressure tight manner by pressing it into a holder of hard material, if the material of

the component can withstand mechanical forces without breaking or being deformed to an unacceptable extent. For use at high pressures, seals of deformable material, e.g. copper, or hard materials are used, which can be compressed under considerable force. In the case of components made of brittle material, the known methods of mounting the component in pressure tight manner give rise to considerable expenditure and require great care. Only limited data can reliably be provided as to the service life of a fluidic component mounted in this way.
The objective is therefore to provide a device for holding a fluidic component, which is also suitable for components made of wear-resistant, hard and consequently usually brittle material, and which does not exhibit any unacceptably high pressure points in the material of the component.
This objective is achieved according to the invention by means of a device for holding a fluidic component which is subjected to a fluid pressure, characterised by
a holder inside which the fluidic component is mounted, and which makes contact with the fluidic component at the low pressure end thereof,
an elastomeric shaped component the outer contour of which corresponds to the inner contour of the holder and the inner contour of which corresponds to the outer contour of the fluidic component whilst
the elastomeric shaped component surrounds the fluidic component around its entire perimeter, and
the elastomeric shaped component has at least one free surface which is exposed to the pressurized fluid.
The elastomeric shaped component is preferably produced by injection moulding, in which the pre-elastomer is transferred free from bubbles into a mould which corresponds to the contours of the holder and the fluidic component. The pre-elastomer hardens in the mould, preferably under pressure.

The elastomeric component may also be produced at the place where it is intended to hold the fluid component.
An elastomeric shaped component of this kind behaves somewhat like an incompressible fluid. It fits perfectly with the holder and the fluidic component.
The elastomeric shaped component surrounds the fluidic component around its entire perimeter. The elastomeric shaped component is exposed to the fluid pressure only at the pressure end, not at the sides where it fits the holder and the fluidic component. The elastomeric component enables the pressure on the fluidic component to be equalised. The elastomeric component does not have any free surface at the low pressure end. The elastomeric component may consist, for example, of natural rubber or synthetic rubber such as silicon rubber or polyurethane.
The fluidic component may consist of wear resistant, hard and hence generally brittle material (such as silicon, glass; ceramic, gemstones, e.g. sapphire, ruby, diamond, or a ductile material having a wear resistant hard surface (such as plastics, copper, hard chromium plated copper, brass, aluminium, steel, steel with a hardened surface)). It may be made in one piece or be assembled from a number of pieces, and these pieces may consist of different materials. The fluidic component can have cavities, recesses or channel structures, e.g. a nozzle structure.
The holder may consist of virtually any desired material, preferably metal or plastics, and can be a rotational body or a body of any desired shape. It may be produced by moulding, casting or by machining.
It may be advisable, e.g. in the case of a cylindrical elastomeric shaped component, to subject the elastomeric shaped component to a constant mechanical force which subjects the elastomeric shaped component to
ft
prestressing. This can be achieved by press fitting or

by means of one (or more) displacement members which exert pressure onto or into the elastomeric shaped component.
The apparatus according to the invention has the following advantages:
No unacceptable local pressure peaks are produced in the fluidic component, since the "floating mount" ensures that the fluid pressure inside and outside the fluidic component is at virtually the same level.
The forces exerted by the holder and the fluid pressure via the fitted elastomeric shaped component onto the fluidic component do not produce any deformation of the fluidic component.
A fluidic component consisting of a material which is to some extent ductile can be clamped in just the same way as a fluidic component made of brittle material.
The mounting of the fluidic component remains sealed even if the fluid pressure abates or a (slight) under pressure is formed.
The mounting is not sensitive to dynamic high pressure loads, e.g. caused by pressure surges.
The fluidic component and the elastomeric shaped component can easily be mounted in the holder without force and with no need for adjustment. For the fluidic component there is no risk of brittle fracture and for the elastomeric component there is no risk of it slipping out of the holder.
It is particularly suitable for a fluidic component of miniature dimensions.
The apparatus in accordance with the invention will be explained in more detail with reference to the drawings.
Figure 1 shows the cylindrical holder 1 made of metal in an oblique view. It has a frustum-shaped recess 2, the diameter of which is somewhat greater at the high pressure end than at the low pressure end. In

its base 3 the holder has an opening 4. The exterior of the holder may be frustum-shaped and the recess may be cylindrical.
Figure 2 shows the elastomeric shaped component 5, the shape of which corresponds to the shape of the holder according to Figure 1 and to the shape of the fluidic component according to Figure 3.
Figure 3 shows a fluidic component 6 consisting of two rectangular plates joined together at their contact surface. At least one of the plates is provided with a channel structure 7 which contains a nozzle on the low pressure side.
Figures 4a and 4b each show a cross-section through another embodiment of the apparatus, each in a plane lying along the axis of the device and in each case parallel to one side of the fluidic component. The holder 8 is provided with a ring 9 which projects beyond the edge of the elastomeric component.
Figure 5 shows a microstructured fluidic component in the form of a nozzle arrangement 10, comprising a base plate 11 and a cover plate 12. To make the drawing clearer, the two plates are shown separately. In the finished state, the two plates are fixed together, so that the fluid which is to be nebulized penetrates through the filter arrangement 13 on the inlet side 16 (high pressure side) into the nozzle arrangement 10 and through the narrow channels 17 and the two wider channels 15 to the nozzle outlet 14 (low pressure side). The plates 11 and 12 may be made of silicon or glass. Other details of the nozzle are disclosed in WO94/07607, to which reference is made herein.

EXAMPLE; Mounting for a Nebulizer Nozzle of Miniature Construction
This device consists of a cylindrical holder made of steel with an external diameter of 3.2 mm and a height of 2.6 mm. It contains a recess with an internal diameter of 2.3 mm at the high pressure end and 2.1 mm at the low pressure end. The base of the holder is 0.4 mm thick and contains a bore 0.8 mm in diameter.
The elastomeric shaped component made of silicon rubber is a frustum. Before it is inserted in the holder it has a diameter of 2.3 mm at the high pressure end and 2.2 mm at the low pressure end and is 1.8 mm high. It contains a recess, symmetrical with its axis, extending along its full height, with a width of 1.0 mm and a length of 1.4 mm.
The fluidic component is a box shape made up of two silicon plates, which is 1.1 mm wide, 1.5 mm long and 2.0 mm high. In the contact surface between the plates it contains a flat, triangular recess 400 µm thick, which terminates in a channel 50 µm wide, 50 µm thick and 200 µm long.
The device is fixed to a container which contains the fluid to be nebulized. The pressure of the fluid inside the fluidic component is 32 MPa (320 bar).

Claims
1. Device for holding a fluidic component which is
exposed to fluid pressure, characterised by
a holder inside which the fluidic component is mounted, and which makes contact with the fluidic component at the low pressure end thereof,
an elastomeric shaped component the outer contour of which corresponds to the inner contour of the holder and the inner contour of which corresponds to the outer contour of the fluidic component whilst
the elastomeric shaped component surrounds the fluidic component around its entire perimeter, and
the elastomeric shaped component has at least one free surface which is exposed to the pressurized fluid.
2. Device according to claim 1 characterised by a
fluidic component made of wear resistant, hard and
consequently usually brittle material (such as silicon,
glass, ceramic, gemstone) or ductile material (such as
plastics or metal, preferably copper, hard chromium
plated copper, brass, aluminium, steel, steel with a
hardened surface) or a combination of these materials.
3. Device according to claim 1 and 2, characterised by
a fluid component which is in one piece or made up of a
plurality of pieces.
4. Device according to claims 1 to 3, characterised by
an elastomeric shaped component made of natural rubber
or synthetic rubber such as silicon rubber or
polyurethane.
5. Device according to claims 1 to 4, characterised by
a microstructured fluidic component of silicon, glass or
silicon/glass having a channel structure.

6. Device according to claims 1 to 5, characterised by
a displacement member which compresses the elastomeric
shaped component.
7. Device according to one of claims 1 to 6,
characterised by a fluidic component in the form of a
nozzle for nebulizing medicinal solutions for
inhalation.
8. Use of a device for holding a fluidic component
according to one of claims 1 to 7 in a nebulizer for
producing propellant-free aerosols for inhalation.
9. Use of a device for holding a fluidic component
according to one of claims 1 to 7, in which a pressure
of up to 600 bar prevails at the high pressure end.

10. Device for holding a fluidic component substantially as hereinbefore described with reference to and as illustrated in the accompanying drawings.

Documents:

2159-DEL-1996-Abstract.pdf

2159-DEL-1996-Claims.pdf

2159-del-1996-correspondence-others.pdf

2159-del-1996-correspondence-po.pdf

2159-del-1996-description (complete).pdf

2159-del-1996-form-1.pdf

2159-del-1996-form-13.pdf

2159-del-1996-form-19.pdf

2159-DEL-1996-Form-2.pdf

2159-del-1996-form-4.pdf

2159-del-1996-form-6.pdf

2159-del-1996-gpa.pdf

2159-del-1996-petition-137.pdf

2159-del-1996-petition-138.pdf

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Patent Number

214870

Indian Patent Application Number

2159/DEL/1996

PG Journal Number

10/2008

Publication Date

07-Mar-2008

Grant Date

18-Feb-2008

Date of Filing

01-Oct-1996

Name of Patentee

BOEHRINGER INGELHEIM INTERNATIONAL GMBH

Applicant Address

D-55216 INGELHEIM AM RHEIN, GERMANY.

Inventors:

#	Inventor's Name	Inventor's Address
1	JOACHIM EICHER	GUSTAV-KORTHEN-ALLEE 24, D-44227 DORTMUND, GERMANY.
2	JOHANNES GESER	BOENSCHSTRASSE 11A, D-44227 DORTMUND, GERMANY.

PCT International Classification Number

B05E1/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	195 36 903.3-51	1995-10-04	Germany