Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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OTOPLASTIC WITH AN INTEGRATED MODULE, IN-EAR OTOPLASTIC
AND METHOD FOR ADAPTING OTOPLASTICS
The present invention relates to an otoplastic, a method for adapting the
otoplastic,
the use of the method and the shell for the otoplastic.
The present invention starts out from problems which
have arisen in conventional hearing devices. The
solution to said problems, however, can also be applied
to other otoplasties, such as headphones for example.
The present invention starts out principally from the
problem that hearing devices to date are produced
integrally and are in most cases replaced as such.
However, -if for example one considers children and
their growing-up, it is evident that, because of this
growth, hearing devices worn outside the ear, and also
very especially in-the-ear hearing devices, have to be
changed in order to keep pace with this growth, which
either means using less expensive hearing devices in
childhood or, if the best hearing devices from the
point of view of acoustic behavior are used right from
the outset, a relatively high cost accrues over the
years.
Even if it were possible, in the case of today's
hearing devices worn outside the ear, to disassemble a
hearing device and provide it with a new shell taking
account of the
growth which has taken place, the
expense in doing so would be great. In the'case of in-
the-ear hearing devices, the expense involved would be
unfeasibly great.
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The object of the present invention is to make
available an otoplasty with integrated module and a
shell surrounding the latter, in particular hearing
devices in which the shell can be changed without great
expense.
According to the present invention, there is provided an otoplastic with
integrated
module and a shell surrounding the latter, characterized in that the shell has
at least
one rubber-elastic portion with an insertion/removal opening for the module.
By this means, it is possible to push or pull the shell
of the otoplasty over the module fitted into the
insertion opening, and likewise to press the module out
of the shell. if appropriate, in order to remove the
module from an existing shell, the latter can be
completely destroyed, for example by being split open,
and discarded in practice as a disposable article,
after which a new shell is pushed on over the module.
According to the present invention there is also provided a method for
adapting the
otoplastic to changing requirements in terms of its external shape,
characterized in
that at the module the shell is changed.
According to the present invention, there is also provided a use of the method
for
hearing devices.
According to the present invention, there is also provided a use of the method
for in-
the-ear otoplastics when changes occur in the auditory canal.
According to the present invention, there is also provided a shell for the
otoplastic,
characterized in that it carries a medicine to be applied to an application
area.
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In a preferred embodiment of the otoplasty according to
the invention, the shell is made of rubber-elastic
material.
In a further much preferred embodiment of the otoplasty
according to the invention, the rubber-elastic
properties of the otoplasty are additionally made use
of by the shell engaging around the module at least
to partially and at least with a form-fit. It is entirely
possible for the shell to engage at least partially
around said module not only with a form-fit, but also,
in the context of the elasticity of the rubber-elastic
material, with rubber-elastic clamping, in other words
with a partial force-fit. It is thus particularly
preferred that the rubber-elastic portion engages
around the module at least partially and at least
partially with a form-fit, it being entirely possible
20 that a shell portion not made of rubber-elastic
material also engages or clamps around the module with
a form-fit or even with a force-fit.
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In a further preferred embodiment, it is proposed that
the opening on the rubber-elastic portion is smaller
than the greatest cross-sectional extent of the module,
viewed in a plane perpendicular to a direction of
insertion of the module into the opening or into the
shell. In this way, a phase plate is in practice
created on the rubber-elastic portion, which phase
plate, after complete insertion of the module into the
shell, closes again at least partially over the module,
once introduced. The module can in this case consist of
one unitary module in which individual subsidiary
modules such as electronic components are already
joined, for example cast, to form one unit, or said
module consists of two or more subsidiary modules which
are then introduced in the correct order into the
shell. The module preferably comprises a battery and/or
one or more electronic modules.
The otoplasty according to the invention is also
preferably an in-the-ear hearing device or a hearing
device worn outside the ear.
The otoplasty according to the invention, as set out
thus far, can be realized both for otoplasties worn
outside the ear and also for in-the-ear otoplasties.
Specifically in the case of in-the-ear otoplasties,
particularly for in-the-ear hearing devices, the object
mentioned at the outset is further achieved by the fact
that its shell consists of at least two parts which can
be detached from one another. It is thus possible, in
the case of in-the-ear otoplasties too, in particular
in-the-ear hearing devices, to disassemble the shell
and to continue using the modules with a new shell or a
new shell part. If, for example for reasons of
cleanliness, one wishes to ensure that a shell part
which has already been in use cannot be used again, the
two parts are designed so that they can be separated
only by destroying at least one of the parts. This can
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be done, for example, by the parts being connected by
way of a catch connection, which can be opened only by
destroying the catch. The parts can also be connected
to and released from one another using locking members,
including bayonet-like closure elements. Here too, it
is further proposed that the shell engages around the
module at least partially and at least with a form-fit.
The module can again be of an integral design and
combine several subsidiary modules or it can be made in
two or more parts. It in this case preferably comprises
at least one battery and at least one electronic
module.
With the otoplasty according to the invention, it is
now possible to change the shell without causing wear
of the integrated modules. Over and above the case of
growth which was mentioned at the outset, this is in
principle also extremely useful when changes occur in
the application area, that is to say changes in the
auditory canal in the case of in-the-ear hearing
devices. However, as a result of the ease with which
the shell of the otoplasty according to the invention
can be changed, shells of hearing devices worn outside
the ear can also be changed in some situations, for
example in order to change the hearing device color or,
generally, its esthetic appearance. However, in the
case of hearing devices worn outside the ear and also,
and in particular, in the case of in-the-ear hearing
devices, a change of shell may also be indicated for
cleanliness reasons, with the otoplasty shell being
changed, in practice as a disposable article, instead
of the relatively expensive cleaning of the otoplasty.
This procedure is used in particular if diseases occur
in the application area, i . e . in the auditory canal in
the case of in-the-ear hearing devices, and sterile
shells have to be fitted at relatively short intervals,
or the shells are actually used as supports for
medicines and then have to be changed anyway as the
healing process progresses. In order to use the
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otoplasty shells as supports for medicine, it is entirely possible for
medicines, for
example medicines diffusing into the surrounding tissue, to be incorporated on
the
outer surface of the shell.
Preferably, to solve the problems mentioned at the outset, the method
according to
the invention, as mentioned at the outset, is characterized in that at least
part of the
otoplasty shell on the module is changed. In a preferred embodiment of the
method
according to the invention, the entire otoplasty shell is changed. In line
with the
above statements, it is proposed, in a preferred embodiment, that the
otoplasty shell
is pushed over the module like a rubber-elastic stocking and, correspondingly,
the
module is pressed out of the otoplasty shell, or, if appropriate, an otoplasty
shell
which is to be changed is destroyed, for example by being split open, and a
new
rubber-elastic shell is pushed on over the exposed module.
Preferably, the method according to the invention is also realized for in-the
ear
otoplasties by virtue of the fact that the otoplasty shell is designed in at
least two
parts, and the parts are separated in order to remove the module, at least one
of the
parts is exchanged and new shell parts are re-assembled with the module. As
has
been mentioned, at least one of the parts can be destroyed upon separation, in
particular both parts if it is intended to make it obligatory in practice to
fit a new shell
or at least a new shell part. The need for obligatory changing of a shell can
readily be
adapted to the duration of use of a battery which is provided.
The method according to the invention is suitable in particular for hearing
devices in
which the modules contained in them are expensive. The method according to the
invention is also suitable for in-the-ear otoplasties when changes occur in
the
auditory canal. Both the otoplasty according to the invention and the
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method according to the invention are further suitable
for changing the otoplasty shell for sterility reasons
and/or for application of medicinal products.
The invention is explained below by way of example and
with reference to the figures, in which:
Fig. 1 shows a simplified diagram of a production
installation operating according to the
preferred production method for optimizing
the industrial production of otoplasties;
Fig. 2 shows a further installation concept, in a
view analogous to that in Fig. 1;
Fig. 3 shows yet another installation concept in a
view analogous to that in Figures 1 and 2;
Fig. 4 shows a diagrammatic view of an in-the-ear
hearing device, with an earwax protection cap
fitted in a known manner;
Fig. 5 shows, in a view analogous to Fig. 4, an in-
the-ear hearing device produced with an
earwax protection cap;
Fig. 6 shows an in-the-ear hearing device with a
ventilation groove formed in it in a known
manner;
Figures 7 (a) through (f) show
novel ventilation grooves on the basis of
perspective views of cutouts of otoplasty
shell surfaces;
Fig. 8 shows, based on a diagrammatic cutout of an
otoplasty surface, a ventilation groove with
a cross section and cross-sectional shape
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varying along its longitudinal extent;
Fig. 9 shows a diagrammatic view of an in-the-ear
otoplasty with lengthened ventilation groove;
Fig. 10 shows, in a view analogous to Fig. 9, an in-
the-ear otoplasty with a plurality of
ventilation grooves;
Figures 11 (a) through (e) show
cutouts of otoplasty shells with ventilation
channels of different cross-sectional shapes
and dimensions formed in them;
Fig. 12 shows, in a view analogous to that in Fig. 8,
a ventilation channel in an otoplasty shell
with a cross-sectional shape and cross-
sectional surface varying along its
longitudinal extent;
Fig. 13 shows, diagrammatically in analogy to the
view in Fig. 9, an in-the-ear otoplasty with
a lengthened ventilation channel formed in
it;
Fig. 14 shows, in a view analogous to Fig. 10, an in-
the-ear otoplasty with a plurality of
ventilation channels;
Fig. 15 shows a diagrammatic view, in longitudinal
section, of an in-the-ear otoplasty with
ribbed inner surface;
Fig. 16 shows a cutout of the otoplasty according to
Fig. 15 in cross section, the ribs having
different cross-sectional surfaces;
Fig. 17 shows a perspective view of the cutout of an
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otoplasty shell with inner ribbing according
to Fig. 15 or 16, the ribs having different
cross-sectional shapes and dimensions along
their longitudinal extent;
Fig. 18 shows, in a view analogous to Fig. 15, an in-
the-ear otoplasty with outer ribbing;
Fig. 19 shows a diagrammatic view of a cutout of a
ribbed otoplasty shell according to Fig. 18,
with ribs having different cross-sectional
surfaces;
Fig. 20 shows a diagrammatic view of a cross section
through an otoplasty with outer ribbing, or
inner ribbing, and an interior at least
partly filled with filler material;
Fig. 21 shows a diagrammatic cutout, in longitudinal
section, of an otoplasty shell with a part
which is flexible upon bending and
compression;
Fig. 22 shows a diagrammatic view, in longitudinal
section, of an in-the-ear otoplasty according
to the invention with a receiving space for
an electronic module;
Fig. 23 shows the otoplasty according to the
invention according to Fig. 22 being pushed
on over an electronic module;
Fig. 24 shows a perspective and diagrammatic view of
an in-the-ear otoplasty according to the
invention, such as in particular an in-the-
ear hearing device, with a two-part,
separable and connectable otoplasty shell;
Fig. 25 shows, in a diagrammatic and cutaway view,
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the integration of acoustic leads and adapter
members to an acoustic/electric or
electric/acoustic transducer, in an
otoplasty;
Fig. 26 shows, in a view analogous to that in Fig.
25, the arrangement of two or more acoustic
leads in the shell of an otoplasty shell, and
Fig. 27 shows, in a simplified signal flow chart and
functional block diagram, a procedure, and an
arrangement for carrying out the procedure,
where the dynamics of the application area of
an otoplasty are taken into consideration
when configuring the latter.
The embodiments of otoplasties which are described
following the production method are preferably all
produced by this described production method.
Definition
An otoplasty is to be understood here as being a device
which is fitted directly outside the auricle and/or on
the auricle and/or in the auditory canal. These include
hearing devices worn outside the ear, in-the-ear
hearing devices, headphones, inserts protecting against
noise and inserts protecting against water, etc.
1. Production method
In the production method preferably used to produce the
otoplasties described in detail hereinafter, the shape
of an individual application area for an intended
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otoplasty is three-dimensionally digitized, and the
otoplasty or its shell is then constructed by an
additive construction method. Additive construction
methods are also known by the term "rapid prototyping".
From the group of these additive methods known today
for rapid prototyping, it appears that laser sintering,
laser lithography or stereolithography, or the
thermojet method are particularly well suited for
constructing otoplasties or their shells, and in this
case in particular the specific embodiments described
hereinafter. Therefore, specifications of these
preferably used additive construction methods will be
discussed here, only in a brief summary:
= Laser sintering: Hot-melt powder is applied in a
thin layer on a powder bed, for example by means
of a roller. The powder layer is solidified by
means of a laser beam, said laser beam being
guided, inter alia according to a cutting layer of
the otoplasty or otoplasty shell, by means of the
3-D shape information of the individual
application area. A solidified cutting layer of
the otoplasty or of its shell is obtained in the
otherwise loose powder. This layer is lowered from
the powder plane, and a new layer of powder is
applied over it, and this layer of powder is in
turn solidified by laser according to a cutting
layer, etc.
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= Laser lithography or stereolithography: A first
cutting layer of an otoplasty or of an otoplasty
shell is solidified by means of W laser on the
surface of liquid photopolymer. The solidified
layer is lowered and is again covered by liquid
polymer. By means of said UV laser, the second
cutting layer of the otoplasty or of its shell is
solidified on the already-solidified layer. Once
again, the laser positioning is controlled inter
alia by means of the 3-D data or information from
the individual, previously recorded application
area.
= Thermojet method: The contour formation in
accordance with a cutting layer of the otoplasty
or of the otoplasty shell is carried out, in the
same way as in an ink-jet printer, by liquid
application inter alia according to the digitized
3-D shape information, in particular also the
individual application area. The deposited cutting
"picture" is then solidified. Once again,
according to the principle of the additive
construction methods, the otoplasty or its shell
is built up by depositing layer after layer.
As regards additive construction methods, and the
preferred ones mentioned above, reference may be made
to the following further publications:
"Selective Laser Sintering (SLS) of Ceramics",
Muskesh Agarwala et al., presented at the
Solid Freeform Fabrication Symposium, Austin,
Texas, August 1999, and
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Donald Klosterman et al., "Direct Fabrication of
Polymer Composite Structures with Curved LOW,
Solid Freeform Fabrication Symposium, University
of Texas at Austin, August 1999, (7)
In principle, therefore, in additive construction
methods, a thin layer of material is in each case
deposited on a surface, either over the whole surface
as in laser sintering or stereolithography, or, as in
the thermojet method, already in the contour of a cut
of the otoplasty or of its shell under construction.
The desired cut shape is then stabilized and
solidified.
Once a layer has been solidified, a new layer is
deposited over this, as has been described, and this
new layer is in turn solidified and connected to the
already solidified layer lying below it. The otoplasty
or its shell is thus constructed layer by layer by
additive layer-by-layer application.
For industrial production, it is preferable not just
for the cutting layer of one individual otoplasty or
otoplasty shell to be deposited and solidified in each
case, but for a plurality to be deposited and
solidified simultaneously per individual. In laser
sintering, for example, the one laser, normally under
mirror control, successively solidifies the cutting
layers of a plurality of otoplasties or their shells,
before all the solidified cutting layers are lowered in
unison. Then, after a new layer of powder has been
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deposited over all the already solidified and lowered
cutting layers, the plurality of further cutting layers
are formed in turn. Despite this parallel production,
the respective otoplasties or their shells are produced
individually by digital control.
in this case, in order to solidify the plurality of
cutting layers, a single laser beam is used and/or
several beams are operated and controlled in parallel.
In an alternative to this procedure, a cutting layer is
solidified with one laser, while at the same time the
layer of powder is being deposited for the formation of
a further otoplasty or otoplasty shell. Thereafter, the
same laser will solidify the prepared layer of powder
according to the cutting layer for the next otoplasty,
while the previously solidified layer is lowered and a
new layer of powder is deposited there. The laser then
operates intermittently between two or more otoplasties
or otoplasty shells under construction, and so the idle
time of the laser occasioned by the deposition of
powder for the formation of one of the shells is
exploited for solidification of a cutting layer of
another otoplasty under construction.
Fig. 1 shows, in a diagrammatic view, how, in one
embodiment, a plurality of otoplasties or their shells
are produced industrially in a parallel process by
means of laser sintering or laser lithography or
stereolithography. The laser with control unit 5 and
beam 3 is mounted above the material bed 1 for powder
or liquid medium. At position 1, it solidifies the
layer S1 of a first otoplasty or its shell, controlled
by the first individual set of data D1. Thereafter, it
is displaced on a displacement device 7 to a second
position where, with the individual set of data D2, it
prepares the layer S2 according to a further individual
contour. Of course, a plurality of the lasers can be
displaced as a unit and in each case several individual
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otoplasty layers are prepared simultaneously. It is
only when the lasers 5 provided have prepared the
respective individual layers at all the intended
positions that a new layer of powder is deposited, in
the case of laser sintering, by the powder delivery
means represented in general at 9, whereas in laser
lithography and stereolithography (not shown) the
solidified layers S are lowered in the liquid bed.
According to Fig. 2, layers of individual otoplasties
or their shells are solidified simultaneously on one or
more liquid or powder beds 1 by a plurality of lasers 5
which are controlled individually and simultaneously.
Once again, after this solidification phase has been
completed and after the lasers have been stopped, the
powder delivery unit 9 deposits a new layer of powder,
whereas, in the case of laser lithography or
stereolithography, the layers which have just
solidified, or already solidified structures, are
lowered in the liquid bed.
According to Fig. 3, the laser 5 solidifies the layer
S1 on a powder or liquid bed la and is then transferred
(broken line) to the bed lb, so that, during the
solidification phase at the bed la, the powder
application device 9b removes powder from above a
previously solidified layer S1_ or, in laser lithography
or stereolithography, the layer S1_ is lowered. It is
only when the laser 5 is active at the bed lb that the
powder delivery device 9a deposits a new layer of
powder over the layer S1 which has just solidified at
the bed la, or the layer S1 is lowered in the liquid
bed la.
When using the thermojet methods, and to similarly
increase productivity, cutting layers of more than one
otoplasty or its shell are deposited simultaneously, in
practice through one application head or, in parallel,
through several in one go.
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By means of the method described, it is possible to
obtain extremely complex shapes of otoplasties or their
shells, specifically as regards both their outer shape,
with individual adaptation to the application area, and
also, in the case of a shell, as regards their inner
shape. Overhangs and inward and outward protrusions can
be readily achieved.
Moreover, materials for additive construction methods
are known which can be shaped to give a rubber-elastic
and yet dimensionally stable shell, which, if so
desired, can be given local differences and even an
extremely thin wall and yet remain resistant to
tearing.
In a presently preferred embodiment, the digitization
of the individual application area, in particular the
application area for a hearing device, in particular an
in-the-ear hearing device, is undertaken in a
specialized institute, in the latter case by an
audiologist. The individual shape recorded there as
digital 3-D information is, particularly in connection
with hearing devices, sent to a production center,
either by transfer of a data carrier or via an Internet
link, etc. The otoplasty or its shell, in the present
case the shell of the in-the-ear hearing device, is
shaped individually at the production center, in
particular using the abovementioned methods. The
fitting of the hearing device with the functional
component groups is preferably also carried out there.
On account of the fact that, as has been mentioned, the
thermoplastic materials used generally lead to a
relatively elastic, conformable outer shape, the
shaping with respect to pressure points in otoplasties
or their shells is also much less critical than was
hitherto the case, which is of huge importance in
particular for in-the-ear otoplasties. Thus, in-the-ear
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otoplasties, for example as ear protectors, headphones,
devices protecting against water, but in particular
also for in-the-ear hearing devices, can be used
similarly to rubber-elastic plugs, and their surface
conforms optimally to the application area, i.e. the
auditory canal. One or more ventilation channels can be
easily incorporated in the in-the-ear otoplasty so
that, with the resulting and possibly relatively tight
fit of the otoplasty in the auditory canal, it is
possible to guarantee unimpaired ventilation as far as
the eardrum. The individual 3-D data from the
application area can also be used during production to
optimize the interior of the otoplasty and utilize this
optimally, including individually with respect to the
individual array of components which this interior is
possibly intended to receive, as in the case of a
hearing device.
Particularly in the case of otoplasties in the form of
hearing devices, centralized production of their shells
permits central storing and administration of
individual data, both with respect to the individual
application area and also to the individual functional
parts and their settings. if, for whatever reasons, a
shell has to be replaced, it can be newly prepared
without any problem by calling up the individual sets
of data, without the need for laborious readaptation,
as has hitherto been the case.
On account of the fact that the methods described for
the production of otoplasties are known and described
in the literature, albeit only for prototyping, it is
not necessary at this point to reproduce all the
technical details of these methods.
At any rate, taking these technologies previously known
from prototyping and using them for industrial and
commercially feasible production of otoplasties
surprisingly affords very considerable advantages,
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specifically for reasons which in themselves are not
critical in prototyping, for example the elasticity of
the thermoplastic materials which can be used, the
possibility of individual construction with extremely
thin walls, etc.
In summary, by using said additive construction methods
for the production of otoplasties or their shells, it
is possible to integrate various functional elements on
them, which functional elements are prepared on
computer during the planning of the otoplasty and which
are generated with the construction of the otoplasty or
its shell. Hitherto, functional elements of this kind
were typically fitted into or onto the otoplasty or its
shell only after the latter had been produced, which is
recognizable from material interfaces or from lack of
homogeneity of the material at the connection points.
For said otoplasties, in particular those with
electronic inserts, for example for hearing devices,
and in particular for in-the-ear hearing devices,
examples of elements which can be fitted directly into
the otoplasty shell by the proposed technique are:
seats and holders for structural parts, earwax
protection systems, ventilation channels in the case of
in-the-ear otoplasties, and support elements which hold
the in-the-ear otoplasty in the auditory canal, for
example channel locks.
Fig. 4 shows, in diagrammatic form, an example of an
in-the-ear otoplasty 11, for example an in-the-ear
hearing device in which the acoustic outlet 13 to the
eardrum is protected by means of an earwax protection
cap 15. This protection cap 15 has hitherto been
produced as a separate part and attached to the shell
16 of the otoplasty 11 and fixed, for example, by
adhesion or welding. As Fig. 5 shows in the same view,
by using said additive construction methods, the earwax
protection cap 15a is integrated directly on the shell
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16a of the otherwise identical in-the-ear otoplasty
lla. At the connection points indicated schematically
at P in Fig. 4, where in conventional methods there is
necessarily a lack of homogeneity of the material or a
material interface, there are no such interfaces
according to Fig. 5, and the material of the shell 16a
merges homogeneously into that of the earwax protection
cap 15a.
This is just an example of how known earwax protection
systems and other functional elements can be integrally
incorporated by using said production method.
A number of specific, novel otoplasties are presented
below:
2. In-the-ear otoplasties with ventilation
In the case of in-the-ear otoplasties, in particular
in-the-ear hearing devices, it is known to provide a
ventilation groove on the outside, as is shown
diagrammatically in Fig. 6. Such ventilation grooves,
as they are used today, are not by any means optimal,
and for different reasons:
As regards acoustics: The ventilation grooves
known today are not really adapted to the
particular acoustic requirements. Thus, in active
otoplasties, for example in-the-ear hearing
devices, they can do little to help effectively
solve the problems of feedback from electro-
mechanical output transducer to acoustic/electric
input transducer. In the case of passive in-the-
ear otoplasties too, for example ear protectors,
they are not able to support the desired
protective action and simultaneously maintain the
desired ventilation properties.
Earwax sensitivity: The ventilation grooves used
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today in the outer surfaces of in-the-ear
otoplasties are extremely sensitive to formation
of earwax. Depending on its intensity, the earwax
formation can quickly impair the ventilation
properties of the ventilation grooves provided, if
not completely obstruct them.
Ventilation measures are proposed below for in-the-ear
otoplasties, in particular for in-the-ear hearing
devices or ear protectors, but also for otoplasties
which extend only partially into the auditory canal,
for example headphones, these ventilation measures at
least partly avoiding the abovementioned disadvantages
of known measures.
In this connection, a distinction is made below between
ventilation systems which
are groove-like and at least partially open toward
the wall of the auditory canal,
are completely closed off from the wall of the
auditory canal.
2a) Ventilation systems open toward the wall of the
auditory canal
in Figures 7(a) through (f), which are perspective
diagrammatic views of cutouts of the outer wall 18 of
in-the-ear otoplasties which bears against the auditory
canal, novel ventilation groove profiles are shown in
cutaway view. According to Fig. 7(a), the profile of
the ventilation groove 20a is rectangular or square
with predetermined and exactly observed dimensional
relationships. According to Fig. 7(b), the profile of
the ventilation groove 20b is in the shape of a sector
of a circle or ellipse, again with an exactly
predetermined cross-sectional edge curve 21b. By exact
determination and execution of the cross-sectional
shape of the ventilation grooves 20 provided, it is
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already possible to a certain extent to predict and
influence the acoustic transmission conditions along
this groove, upon bearing against the inner wall of the
auditory canal. Of course, the acoustic behavior also
depends on the length by which the groove 20 extends
along the outer wall 18 of the otoplasty.
Figures 7(c) through (f) show further ventilation
groove profiles which are additionally protected
against earwax. The profile of the groove 20c according
to Fig. 7(c) is T-shaped.
Regarding the wide cross-sectional surface of the
groove at 27c, the inwardly jutting portions 23c and
the resulting constriction 25c, toward the wall of the
auditory canal, already give a considerable protective
action against earwax. Even if earwax penetrates into
the constriction 25c and hardens there, this does not
cause any real constriction or even blockage of the
ventilation groove, which now becomes an enclosed
ventilation channel. In Figures 7(d) through 7(f),
which follow the principle of Fig. 7(c) already
explained, the cross-sectional shape of the wide groove
portion 27d through 27f is designed with different
shapes: in Fig. 7(d) in the shape of a sector of a
circle or the sector of an ellipse, in Fig. 7(e) in the
shape of a triangle, and in Fig. 7(f) in the shape of a
circle or ellipse.
By specific configuration of the cross-sectional
surface of the groove, shown simply by way of example
in Figures 7(a) through 7(f), it is already possible to
achieve a considerably improved effect, both with
respect to the acoustic properties and also with
respect to the protection against earwax, compared to
conventional ventilation grooves which have more or
less random profiles. In this case, the profiles are
first computer-modeled, taking into consideration said
protection against earwax and the acoustic effect, and
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are integrated exactly into the finished otoplasties.
The additive construction methods discussed above are
very particularly suitable in this respect. In order
now to further optimize the acoustic effect of the
ventilation groove, a very wide variety of acoustic
impedances can be obtained along the length of the
novel ventilation grooves, which results, for example
as in Fig. 8, in ventilation grooves 29 defining
different profiles along their longitudinal extent,
which in Fig. 8 are made up of profiles according to
Fig. 7.
Like the configuring of passive electrical networks,
the acoustic transmission behavior of the groove which
bears on the auditory canal can thus be computer-
modeled and checked and then integrated into the in-
the-ear otoplasty or its shell.
More areas protected against earwax can be specifically
provided on exposed portions for this purpose, as is
indicated at A in Fig. B.
Moreover, with a view to optimizing the acoustic
conditions, it may be entirely desirable for the
provided ventilation grooves to be made longer than is
permitted in principle by the longitudinal extent of a
given in-the-ear otoplasty. As is shown in Fig. 9, this
is achieved by the fact that such grooves 31, designed
in the manner shown for example in Figures 7 and 8, are
guided in predetermined curves along the surface of the
otoplasty, for example as is shown in Fig. 9, in
practice as grooves running round the otoplasty like a
thread. Further optimization flexibility is achieved by
the fact that not just one ventilation groove, but a
plurality are guided across the surface of the
otoplasty, as is shown diagrammatically in Fig. 10. The
high degree of flexibility of the groove design means
that, depending on the application area in the auditory
canal, differently dimensioned ventilation grooves
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specifically optimized in each case with respect to
earwax protection and acoustic transmission behavior
can be formed along the surface of the otoplasty.
2b) Ventilation systems with fully integrated channels
This alternative embodiment of the novel ventilation
systems is based on ventilation channels which are
fully integrated into the otoplasty, at least in some
areas, and closed off from the wall of the auditory
canal. This system is explained below on the basis of
its design on an otoplasty shell. It should be
stressed, however, that when no other units are to be
integrated on the otoplasty in question and the latter
is designed as a solid otoplasty, the following
explanations naturally relate also to a channel passage
in any form right through said solid otoplasty.
Fig. 11 shows, in analogy to Fig. 7, different cross-
sectional shapes and surface relationships of the
proposed ventilation channels 33a through 33e.
According to Fig. 11(a), the ventilation channel 33a
built into the otoplasty shell 35a has a rectangular or
square cross-sectional shape. In the embodiment
according to Fig. 11(b), it has, at 35b, a channel
cross-sectional shape in the form of a sector of a
circle or sector of an ellipse. In the embodiment
according to Fig. 11(c), the ventilation channel 33c
provided has a circular or elliptic cross section, and,
in the embodiment according to Fig. 11(d), it has a
triangular cross-sectional shape.
In the embodiment according to Fig. 11(e), the
otoplasty shell has a complex inner shape, for example
a retention part 37 integrated thereon. For optimal
utilization of space, the ventilation channel 35e
provided here is designed with a cross-sectional shape
which also makes use of complex shapes of the otoplasty
shell. Accordingly, its cross-sectional shape extends
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in a complicated manner partially into the retention
strip 37 built onto the shell 35e.
Looking back at the variant embodiment in accordance
with section 2a), it should be noted that these complex
cross-sectional shapes optimally utilizing the
available space can also be realized on ventilation
grooves which are open toward the auditory canal, and,
conversely, channel passages as shown for open grooves
in Figures 9 and 10 can be realized on closed
ventilation channels.
Fig. 12 shows, finally, an alternative embodiment of a
fully integrated ventilation channel 39 which has
different cross-sectional shapes and/or cross-sectional
dimensions along its longitudinal extent, as is
represented for example in the otoplasty shell 41, in
which case the acoustic transmission behavior can be
optimized in the sense of executing different acoustic
impedance elements. In this connection, and with
reference to subsequent section 5), it may also be
noted that, because of the possibility of realizing
complex acoustic impedance conditions, ventilation
channels, in particular of the closed configuration
presented in this section, can at the same time be
used, at least in some sections, as acoustic lead
sections on the output side of active electromechanical
transducers, for example on the output side of
microphones, for example in in-the-ear hearing devices.
Figures 13 and 14, in analogy to Figures 9 and 10,
show, on the one hand, how the integrated ventilation
channels discussed in this section are lengthened on
the respective otoplasty 43 by appropriate guiding of
their course, and, on the other hand, how two and more
of said channels, if appropriate with different and/or
varying channel cross sections, in analogy to Fig. 12,
are integrated on the otoplasty.
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The possibilities which are presented in sections 2a)
and 2b), and which can also be combined in any desired
manner, afford the skilled person a countless number of
design variants of the novel ventilation systems and in
particular, because of the different independently
dimensionable parameters, a large degree of freedom in
creating optimum earwax protection and optimum acoustic
transmission conditions for the respective individual
otoplasty. In all the embodiment variants, the specific
individual configuration of the system is preferably
calculated or computer-modeled, taking the stated
requirements into account. The individual otoplasty is
then made. Once again, the production method with the
additive construction principle, which is known from
prototyping and which is explained in the introduction,
is suitable for this purpose, which method is then
controlled with the optimized model result.
3. Otoplasties with optimized shape stability
This section deals with providing novel otoplasties
which are optimally adapted to the dynamics of the
application areas. It is known, for example, that
conventional in-the-ear otoplasties are unable to
accommodate the relatively great dynamics of the
auditory canal, for example during chewing, because
their shape stability is substantially identical in all
parts. Similarly, for example, the acoustic leads
between hearing devices worn outside the ear, and the
auditory canal are unable to freely follow the dynamics
of the application area. The same problem arises with
in-the-ear otoplasties, to a slightly lesser extent,
and also with ear protectors, headphones, inserts
protecting against water, etc. In particular, their
intrinsic function, for example their protective
action, in this case partially deteriorates if the
stated dynamics of the application area are
increasingly taken into consideration. By way of
example, reference may be made in this connection to
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known ear protectors which are made of elastically
deformable plastics and which indeed take considerable
account of the stated dynamics of the application area,
but at the expense of their acoustic transmission
behavior.
Fig. 15 shows a diagrammatic view of a longitudinal
section of an in-the-ear otoplasty, and Fig. 16 shows a
diagrammatic cross-sectional view of a portion of this
otoplasty. The otoplasty, for example for receiving
electronic components, has a shell 45 which is made,
like a pair of tights, as a thin wall of elastic
material. The shape stability of the shell skin, which
is smooth on the outside in the illustrative embodiment
shown, is ensured, where so desired, by ribs 47 which
are applied integrally on the inside of the shell and
which are made of the same material as the shell skin.
Depending on the required dynamics of the in-the-ear
otoplasty on the one hand, in order for example to take
account of the dynamics of the auditory canal, and the
requirements in respect of the support and protection
of built-in components, as in an in-the-ear hearing
device, the course of the wall thickness of shell skin
45 and the density and configuration of the ribs 47 are
calculated in advance, and the otoplasty is thereafter
constructed according to the calculated data. Once
again, the above-discussed production method using
additive construction methods is outstandingly suitable
for this purpose. Of course, the design of the in-the-
ear otoplasty just discussed can be readily combined
with a ventilation system of the kind discussed with
reference to Figures 7 through 14. In particular, the
ribs provided to influence the shape stability or
bendability can also be designed with different cross-
sectional profile in certain areas of the otoplasty, if
appropriate also advancing from one cross section to
the other in their longitudinal extent.
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In the form of a perspective view, Fig. 17 shows purely
by way of example and diagrammatically the design of
the outer skin 45 with ribs 47 having varying cross-
sectional surfaces along their longitudinal extent.
Instead of or in addition to the specific wall
strengthening and the specific configuration of the
bending and torsion behavior, in short of the shaping
behavior of the in-the-ear otoplasty, it is possible,
as has been mentioned, in addition to the internal
ribbing pattern as is shown in Figures 17 and 18, also
to provide an external ribbing pattern. According to
Figures 18 and 19, a pattern of ribs 51 is worked on
the outer surface of the otoplasty 49, if appropriate
with different density, orientation and profile shape
in different areas.
According to Fig. 19, this can be used for the
otoplasties in question here which have a hollow
cavity, but also for otoplasties with no hollow cavity,
that is to say, for example, with no electronic
components, e.g. for ear protector devices and devices
protecting against water. One such otoplasty is shown
diagrammatically in a cross-sectional view in Fig. 20.
Here, the interior 53 is made, for example, from
extremely compressible absorption material and is
surrounded by a shape-giving skin shell 55 with rib
pattern 57. Here, the "skin" 55 and the rib pattern 57
are integrally produced together. The production method
discussed in the introduction and using additive
construction methods is once again suitable for this
purpose. How far these additive construction methods
will be able to be used, in the near future, on a
workpiece with changing of the processed materials
remains to be seen. Should this become possible, then
the way is clear, for example in the illustrative
embodiment according to Fig. 20, to sequentially also
construct the filler 53 at the same time as the shell
skin 55 and the ribs 57 in respective construction
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layers.
Looking back in particular to Figures 18 and 19, it
will be seen that ventilation channels or free spaces
can at the same time be formed with the aid of the
external ribbing pattern, as is shown purely
schematically and by way of example by the path P.
Returning once more to Fig. 20, it is entirely
possible, if so required, and as is shown by broken
line 57i in Fig. 20, to provide an internal ribbing
pattern 57i on the shell skin 55 even if the in-the-ear
otoplasty is filled with material, that is to say if it
is not intended to receive further components, such as
electronic components. As is also shown by the broken
line 59 in Fig. 20, otoplasties can also be created
which indeed leave free a hollow cavity to receive
units such as electronic components, but in which the
interspace, between such a hollow cavity 59, is
designed specifically to the necessary volumes and
shapes of the units additionally to be received, and
the shell skin 55 is filled for example with a
resilient or sound-damping material, or components to
be incorporated are surrounded by such a material as
far as the shell skin 55.
The shell skin 55 or 45 according to Figures 15, 16 and
17 can be made entirely of electrically conductive
material, by which means an electrical screening effect
is at the same time created for electronic components
lying on the inside. This also applies, if appropriate,
to the filling 53 according to Fig. 20.
Figures 15 through 20 have shown an example of an
otoplasty in the form of an in-the-ear otoplasty whose
shell is shape-stabilized with ribs lying on the inside
and/or outside, resulting in an extraordinarily light
and deliberately formable structure. If necessary, this
structure can of course also be used for otoplasties
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worn outside the ear.
Fig. 21 shows a further alternative embodiment of an
in-the-ear otoplasty which is deliberately bendable or
compressible in one area. For this purpose, the shell
61 of an otoplasty, such as in particular the shell of
an in-the-ear hearing device, has an undulated or
creased configuration 63 at one or more predetermined
regions where, in accordance with the particular
requirements, it is bendable or compressible. Although
Fig. 21 shows this measure on the basis of the shell of
an in-the-ear otoplasty, it is entirely possible, if
necessary, to provide this measure also for an
otoplasty worn outside the ear. For this purpose, the
production method discussed in the introduction is once
again preferably used.
In this illustrative embodiment too, it is possible, as
was explained with reference to Fig. 20, for the
internal volume of the otoplasty to be filled with
filler material in accordance with the requirements,
and built-in components integrated therein can be
embedded in such filler material, resulting in a higher
degree of stability of the appliance and improved
acoustic conditions.
4. Modular housing/built-in components
Particularly in the case of in-the-ear hearing devices,
the problem is that the application area, i.e. the
auditory canal, changes its shape. This is obviously
the case when a person is growing up. In adults too,
however, the auditory canal changes, sometimes
considerably, and in most cases in the sense of
narrowing (e.g. what is called diver's ear).
In the case of in-the-ear hearing devices, the problem
thus generally arises that, even if the components
built into the hearing device could themselves be
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maintained over long periods of the user's life, for
example with only the transmission behavior of the
hearing device having to be readjusted to the
particular hearing conditions, new hearing devices
nevertheless have to be constantly designed, simply
because of the fact that the previous ones no longer
fit satisfactorily into the auditory canal.
The measures discussed in section 3 already make it
possible to improve this, on account of the fact that
automatic shape adjustment of the otoplasty to the
changing application areas is thus permitted. In this
section, further measures in this connection will be
discussed, particularly with reference to in-the-ear
otoplasties. However, it should be noted that also in
the case of otoplasties worn outside the ear, for
example hearing devices worn outside the ear, this
opens up the possibility of changing the "housing", and
of doing so not only when this is necessary for reasons
of wearing comfort, but also as and when desired, for
example in order to change the esthetic appearance of
such hearing devices worn outside the ear.
Fig. 22 shows a diagrammatic view of an in-the-ear
otoplasty 65 in longitudinal section, the design of the
interior 67 corresponding substantially to the shape of
the electronic module 69 to be received, which is shown
diagrammatically in Fig. 23. The otoplasty 65 is made
of rubber-elastic material and, as is shown in Fig. 23,
can be pushed on over the electronic modules 69. The
shaping of the interior 67 is such that the module or
the plurality of modules to be received are positioned
and held directly with a form fit by the otoplasty 65.
By means of this measure, it is easily possible to
provide one and the same electronic modules 69 with.
different otoplasties 65, for example in order thereby
to take account of the changing shape of the auditory
canal in a growing child. The otoplasty in practice
becomes an easily exchangeable throw-way accessory for
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the in-the-ear hearing device. The otoplasty 65 can be
easily changed not only to take account of changing
conditions in the application area, namely the auditory
canal, but also simply for reasons of soiling. This
concept can even be used, if appropriate, for example
in cases of inflammation of the auditory canal, to
apply medicines, for example by application of
medicines to the outer surface of the otoplasty, or at
least in order to use sterilized otoplasties at regular
intervals.
The concept shown with reference to Figures 22 and 23
can of course be combined with the concepts set out in
sections 2) and 3), and the otoplasty 65 is preferably
produced using the production method discussed in
section 1), which permits the design of highly complex
internal shapes for receiving the module 69 in a manner
free from play and vibration.
As can be seen from Figures 22 and 23, the phase plate
1 otherwise provided in conventional in-the-ear hearing
devices is built integrally with the otoplasty, for
example as part of the module holder. The same applies
to other holders and receiving seats for electronic
components of the hearing device. If the layer-by-layer
construction method set out in section 1) is carried
out, as is indicated by broken lines in Fig. 22 and in
the direction shown by the arrow AB, then it ought to
be easily possible to produce the otoplasty from
different materials in said construction direction AB,
according to the requirements in the respective areas.
This applies also to the otoplasties set out in
sections 2) and 3), and to those discussed in sections
5), 6) and 7) below. Taking the example in Fig. 22, it
is thus quite possible to produce the area 65a using
rubber-elastic material, and by contrast the outlet
area 65b using more shape-stable material.
Fig. 24 shows a further embodiment of an otoplasty,
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again taking the example of an in-the-ear hearing
device, which allows the internal built-in components
to be easily and quickly changed. In principle it is
proposed here that the otoplasty shell of an in-the-ear
otoplasty with built-in components is designed in a
plurality of parts which can be fitted together, as is
shown in Fig. 24. By means of quick-acting couplings,
such as snap-in couplings, catches or even bayonet-like
couplings, it is possible for housing parts 73a and 73b
of the in-the-ear otoplasty to be quickly separated
from one another, for the built-in components such as
electronic modules to be removed, and for these to be
inserted again into a new shell, if appropriate with
different outer shape, or in principle into a new shell
even when this is necessary, for example, for cleaning
reasons, sterility reasons, etc. If provision is made
for the already used shell to be disposed of, it is
easily possible to design the connections of the shell
parts in such a way that the shell can only be opened
by destroying it, for example by providing locking
members, such as catches, which are not accessible from
the outside and by the shell being cut open in order to
remove them.
This embodiment can of course also be combined with the
alternative embodiments described above and those still
to be described.
5. Integration of acoustic leads in otoplasties and
their shells
In hearing devices worn outside the ear, and also in
in-the-ear hearing devices, it is customary for the
provided acoustic/electric transducers or electro-
acoustic output transducers to be coupled, on the input
side or output side, to the environment of the hearing
device via acoustic leads assembled as independent
parts, namely tube-like structures, or, in particular
with acoustic/electric transducers on the input side,
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to place these with their receiving surface immediately
in the area of the surfaces of the hearing device, if
appropriate separated from the environment only by
small hollow spaces and protective measures.
In the design of such hearing devices, there is
therefore a relatively large join where the actual
transducers are to be provided in the hearing device
and where the actual coupling openings to the
environment are to be provided on said hearing device.
As regards the arrangement of coupling openings to the
environment and the arrangement of said transducers
inside the hearing device, it would be highly desirable
to have the greatest possible design freedom.
This is in principle achieved by the fact that said
acoustic leads - at the input side of acoustic/electric
transducers or output side of electric/acoustic
transducers - are integrated into the otoplasty or into
the wall of otoplasty shells.
This is shown purely schematically in Fig. 25. A
transducer module 75 has an acoustic input/output 77.
The shell 79 of the otoplasty of an in-the-ear hearing
device, or of a hearing device worn outside the ear, or
of headphones, has an acoustic lead 81 integrated
within it. This lies at least partially within the wall
of the otoplasty shell 79, as is shown in Fig. 25. The
respective acoustic impedance of the acoustic lead 81
is preferably adapted by means of acoustic stub lines
or line sections 83. This concept, taking the example
of hearing devices worn outside the ear, makes it
possible to provide acoustic input openings 85
staggered along the hearing device and at desired
locations, and to couple said inlet openings 85 to the
provided acoustic/electric transducers 91 via acoustic
leads 89 integrated in the otoplasty or its shell 87,
and largely irrespective of where these transducers 91
are built into the hearing device. Thus, Fig. 26 shows,
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only by way of example, how two transducers are
centralized into one module and their inputs are
connected to the desired receiving openings 85 via said
path of the acoustic leads 89. In the light of Figures
25 and 26 and the statements in section 2) regarding
the novel ventilation systems, it will be evident that
it is quite possible to use ventilation channels also
as acoustic lead channels, especially if, as is shown
diagrammatically in Fig. 25, the acoustic impedance
conditions are specifically configured by means of
acoustic adapter members 83.
6. Identification of otoplasties
In the production of otoplasties, in particular of in-
the-ear otoplasties, each one is individually adapted
to its respective wearer. For this reason, it would be
highly desirable to identify each finished otoplasty,
as mentioned in particular each in-the-ear otoplasty,
and very particularly each in-the-ear hearing device.
it is therefore proposed to provide an individual
identification in the otoplasty or its shell by means
of indentations and/or embossings, which
identification, in addition to giving the individual
orderer, for example manufacturer, can contain the
product serial number, left/right application, etc.
Such an identification is created in a much preferred
manner during the production of the otoplasty using the
removal method described under 1). This ensures that
any mix-up of the otoplasties is ruled out starting
from the time of production. This is particularly
important in the subsequent and possibly automatic
fitting with further modules, for example the fitting
of in-the-ear hearing devices.
This measure can of course be combined with one or more
of the aspects described under sections 2) through 5).
7. Optimization of otoplasties with respect to the
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dynamics of the application area
When molding otoplasties for in-the-ear application,
for example for in-the-ear hearing devices, it is at
present customary to take an impression of the auditory
canal, for example using silicone. If one now considers
the quite substantial dynamics of movement of the
auditory canal, for example during chewing, it is
evident that basing the shape of the in-the-ear
otoplasty on an impression, which corresponds in
practice to a momentary record, can scarcely yield a
result which will be entirely satisfactory in use. As
is now shown in Fig. 27, which is a simplified
functional block diagram/signal flow chart, a mold is
taken from the dynamic application area, represented by
the block 93, at several of the positions corresponding
to the dynamics occurring in practice, or the dynamics
of the application area are recorded per se in the
manner of a film. The resulting data sets are stored in
a memory unit 95. Also in the conventional procedure
with impression-taking, this can be readily done by
taking impressions, corresponding to the practical
dynamics, of the application area at two or more
positions.
These impressions are then scanned and the respective
digital data sets are stored in the memory unit 95. As
a further possibility, the dynamics of the application
area can be recorded by X-ray, for example.
Thus, depending on the accuracy which is to be
achieved, a number of "images" or even in practice a
"film" of the pattern of movement of the application
area in question are recorded. The data recorded in the
memory unit 95 are then fed to a computer unit 97. At
its output, the computer unit 97 controls the
production process 99 for the otoplasty. If, for
example, as is still customary today, in-the-ear
otoplasties are produced with a relatively hard shell,
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the computer unit 97 uses the dynamics data stored in
the memory unit 95 and, if appropriate, further
production parameters as shown schematically at K, to
calculate the best matching shape for the otoplasty, so
that optimum wearing comfort in everyday use is
achieved while maintaining its functionality. If the
otoplasty to be produced is realized using the
principle set out in section 3), the computer unit 97
determines which otoplasty areas are to be configured
and how in terms of their flexibility, bendability,
compressibilty, etc. At its output, the computer unit
97, as has been stated, controls the production process
99, preferably in this case the production process as
was set out in section 1) as the preferred process.
