U.S. patent application number 14/612450 was filed with the patent office on 2015-05-28 for dual-function spring.
The applicant listed for this patent is TecPharma Licensing AG. Invention is credited to ADRIAN EICH, Aurele Horisberger, Patrick Hostettler, Malte Kladiwa, Stefan Meier, Peter Stettler, Jurgen Wittmann.
Application Number | 20150148754 14/612450 |
Document ID | / |
Family ID | 40756893 |
Filed Date | 2015-05-28 |
United States Patent
Application |
20150148754 |
Kind Code |
A1 |
EICH; ADRIAN ; et
al. |
May 28, 2015 |
DUAL-FUNCTION SPRING
Abstract
An injection device for dispensing a product, the injection
device including a moveable element which is moved for a dispensing
operation, a spring, a product container holder and a product
container, wherein the spring pushes against the moveable element
to move the moveable element to an initial position after the
dispensing operation has ended and against the product container to
seat the product container in the product container holder.
Inventors: |
EICH; ADRIAN; (Wangenried,
CH) ; Horisberger; Aurele; (Allschwil, CH) ;
Hostettler; Patrick; (Hasle-Ruegsau, CH) ; Kladiwa;
Malte; (Bern, CH) ; Meier; Stefan; (Aarberg,
CH) ; Stettler; Peter; (Kirchberg, CH) ;
Wittmann; Jurgen; (Burgdorf, CH) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
TecPharma Licensing AG |
Burgdorf |
|
CH |
|
|
Family ID: |
40756893 |
Appl. No.: |
14/612450 |
Filed: |
February 3, 2015 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
12869362 |
Aug 26, 2010 |
8992487 |
|
|
14612450 |
|
|
|
|
PCT/CH2009/000078 |
Feb 26, 2009 |
|
|
|
12869362 |
|
|
|
|
Current U.S.
Class: |
604/235 |
Current CPC
Class: |
A61M 5/31543 20130101;
A61M 5/31583 20130101; A61M 2005/244 20130101; A61M 2005/2086
20130101; A61M 5/31558 20130101; A61M 2005/2407 20130101; A61M
5/31541 20130101; A61M 2005/2481 20130101; A61M 5/31561 20130101;
A61M 2005/2488 20130101; A61M 5/3129 20130101; A61M 2005/2477
20130101; A61M 5/20 20130101; A61M 2005/2433 20130101; A61M 5/31553
20130101; A61M 2005/2403 20130101; A61M 2005/202 20130101; A61M
5/24 20130101 |
Class at
Publication: |
604/235 |
International
Class: |
A61M 5/24 20060101
A61M005/24 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 29, 2008 |
DE |
10 2008 011 885.0 |
Claims
1. An injection device for dispensing a product, the injection
device comprising a moveable element which is moved for a
dispensing operation, a spring, a product container holder and a
product container, wherein the spring pushes against the moveable
element to move the moveable element to an initial position after
the dispensing operation has ended and against the product
container to seat the product container in the product container
holder.
2. The injection device as claimed in claim 1, wherein the spring
is disposed between the moveable element and the product
container.
3. The injection device as claimed in claim 2, wherein the spring
is one of a separate part or a part formed by the moveable
element.
4. The injection device as claimed in claim 1, wherein the spring
acts on the product container directly or via a retainer.
5. The injection device as claimed in claim 4, wherein at least one
of the spring and the retainer comprises a stop which prevents the
spring from fully relaxing when no product container is
inserted.
6. The injection device as claimed in claim 1, wherein the moveable
element comprises part of a coupling and is moved out of the
coupling for a dispensing operation.
7. The injection device as claimed in claim 1, wherein the moveable
element is able to move axially relative but not rotate.
8. The injection device as claimed in claim 1, further comprising
an output element which acts on the product to be dispensed to
dispense the product via a plunger which is moveably accommodated
in the product container, and the moveable element is coupled with
the output element so that it blocks a dispensing movement of the
output element when the injection device is in a non-secured
state.
9. The injection device as claimed in claim 8, wherein the
dispensing movement of the output element is a rotating
movement.
10. The injection device as claimed in claim 8, further comprising
an axially displaceable operating element which can be operated by
a user of the injection device, wherein, when the operating element
is operated, the moveable element is moved axially so that the
output element is released for a movement in or opposite a
dispensing direction.
11. The injection device as claimed in claim 8, further comprising
a locating element which can be moved in an engaged connection to
the output element and between a first position and a second
position, and the output element is uncoupled from the moveable
element in the first position so that the output element can be
moved in or opposite a dispensing direction.
12. The injection device as claimed in claim 11, wherein the
locating element is coupled with a fixing device so that it is
moved axially when the product container is being secured or
released.
13. The injection device as claimed in claim 10, wherein the
operating element can be re-set by the spring.
Description
CROSS-REFERENCED RELATED APPLICATIONS
[0001] This application is a continuation of International Patent
Application No. PCT/CH2009/000078 filed Feb. 26, 2009, which claims
priority to German Patent Application No. 10 2008 011 885.0 filed
Feb. 29, 2008, the entire contents of each of which are
incorporated herein by reference.
BACKGROUND
[0002] The present invention related to devices for injecting,
infusing, administering, dispensing or delivering a substance, and
to methods of making and using such devices. More particularly, the
present invention relates to an injection device for administering
a substance or product such as a medicament or therapeutic
substance, e.g. insulin, growth hormone, etc.
[0003] The idea of coupling an ampoule (which also may be referred
to and/or thought of as a container, carpoule, vial or the like)
containing a product to or in an injection device is known from the
prior art. Securing an ampoule in a stationary seating, for example
in an ampoule holder, when attached to the injection device is also
known. In some cases, the ampoule may be screwed into the holder,
and the securing or holding may be achieved by a clamping action
wherein the product container accommodated in the ampoule holder is
clamped between the distal (forward) end of the ampoule holder and
a stop which acts on the distal end of the ampoule.
SUMMARY
[0004] An object of the present invention is to provide an
injection device to which a product container can be secured in a
reliable, efficient and economic manner.
[0005] In one embodiment, the present invention comprises an
injection device for dispensing a product, the injection device
including a moveable element which is moved for a dispensing
operation, a spring, a product container holder and a product
container, wherein the spring pushes against the moveable element
to move the moveable element to an initial position after the
dispensing operation has ended and against the product container to
seat the product container in the product container holder.
[0006] In one embodiment of an injection device according to the
present invention, the device comprises coupling element, a product
container, and a spring between the coupling element and the
product container, the spring biasing or urging the coupling
element in one direction and the product container in the other,
i.e. opposite, direction.
[0007] In some embodiments, the present invention comprises an
injection device whereby an injection may be administered manually
by the user or may take place automatically. For example, a user of
an embodiment of the device designed for automatically dispensing
the product may operate an operating element which releases a drive
element, for example a spring, and the spring force acts indirectly
or directly on an output element and/or pushes the plunger of a
product container in a dispensing direction. The drive element may
be a motor, a pyrotechnic propellant charge or, as in some
preferred embodiments of the present invention, a spring, e.g. a
mechanical spring. If the drive element is of the type which stores
energy, in some preferred embodiments the stored energy can be
released by an operating element so that a driving movement can be
converted into an output movement. In some embodiments, the driving
movement may be a rotating movement, and the output movement may be
a linear movement.
[0008] In some preferred embodiments, the drive element may be a
rotating spring, e.g. a helical or clock spring, which is wound
about the longitudinal axis of the injection device. For example,
the spring may be supported in a fixed arrangement on the housing
in at least one direction of rotation by one end and connected to
the output element or a part which is or can be coupled with the
output element by the other end. Thus, the rotational energy stored
in the spring may be converted into a driving movement. In some
embodiments, it is advantageous to use a strip-shaped helical
spring.
[0009] In some embodiments, an injection device in accordance with
the present invention may be disposable. Generally, in such
embodiments, a product container inserted or built into the device
during production can not be replaced, and when empty or after the
injection device has been used, it is disposed of as a whole
together with the product container.
[0010] In some embodiments, an injection device in accordance with
the present invention is designed to be used more than once. This
is practical if the injection device is fitted with high-quality
and/or high-tolerance components designed to make it easy to
dispense a product and which may be too expensive for use with
disposable items. In some embodiments, a driving mechanism is
incorporated in a drive unit, in which case the product container
can be attached to the drive unit, and can be detached from the
drive unit. An empty product container can be released from the
drive unit, disposed of and replaced by a new one.
[0011] In some preferred embodiments, the product container is
received and/or seated in a product container holder. The product
container holder is sleeve-shaped and has an opening through which
the product container can be inserted into the interior of the
sleeve. The opening may be disposed laterally or on an end, e.g.
the proximal (rear) end, of the product container holder. At the
side, the product container holder may have a region through which
it is possible to see from the outside into the interior of the
container to, for example, ascertain whether a product container
has been inserted or to check how full an inserted product
container is. The product container holder may have a collar at its
distal (forward) end, against which the product container sits in
an abutting contact in its inserted state. The product container is
then fixedly seated in the product container holder. The product
container holder may have a conical shape, and the product
container can be pushed into it to obtain a fixed seating.
[0012] In some preferred embodiments, an injection device in
accordance with the present invention, e.g. the drive unit thereof,
may comprise a spring element, such as a mechanical spring, a gas
compression spring or other elastic means, which acts on or pushes
on the product container, e.g. the part of the product container
relative to which the plunger can be displaced. In some preferred
embodiments, the spring element may push the product container into
a fixed seating with and/or within the product container holder. In
some preferred embodiments, the spring element may act in the
longitudinal direction of the injection device.
[0013] In some embodiments of the present invention, the product
container may be an ampoule or capped vial, for example, and is
open at its proximal (rear) end and closed at its distal (forward
or front) end. An output element of the drive unit may extend
through the proximal end into the product container to act on a
plunger or piston in the container, which plunger or piston can be
displaced relative to the product container wall. The distal end
may incorporate or carry a needle, or may be designed so that a
needle can be attached, thereby establishing a flow connection to
the interior of the product container due to the fact that the
needle pierces a septum disposed on the distal end of the product
container. In some preferred embodiments, the wall of the product
container is cylindrical, and it may be tightly enclosed by the
sleeve-shaped product container holder or enclosed with a slight
clearance.
[0014] In some embodiments, the injection device may have an
element which is moved back into an initial position after a
dispensing operation has ended or as it is ending. This may be an
operating element which can be operated by moving it, e.g. by
moving it axially along a longitudinal axis of the injection
device. The element may be moved into a dispensing position as the
dispensing operation is being actuated or triggered, in which case
the direction of movement needed for this purpose is opposite the
direction of movement in which the element can move on terminating
the dispensing operation. The operating element may be operated by
a user of the device to trigger and/or stop dispensing of the
product, or it may be released after the product has been dispensed
whereby it moves back or automatically returns to its initial
position. A lock element may be coupled with the operating element
so that it is axially locked, at least in one direction and, in
some preferred embodiments, in both directions.
[0015] In some embodiments, the operating element moves back or can
be moved back to an initial position after the dispensing operation
has terminated. Thus, an injection device in accordance with the
present invention may comprise a coupling, e.g. a coupling element
which establishes or releases a coupling as it is moved. For
example, such a coupling element may be coupled with the operating
element in at least one direction and at least for a certain time.
The coupling element may push the operating element in one
direction, and in the other, opposite direction, the operating
element may push the coupling element.
[0016] In some preferred embodiments, the element which is moveable
when a dispensing operation is terminated or triggered may be moved
back into an initial position by a spring element when the
dispensing operation has terminated. The spring element may also
urge the product container into its fixed seating. In some
preferred embodiments, the spring element is a helical spring,
which may be wound from a wire-like material. The spring element
may be disposed parallel and/or concentrically with the
longitudinal axis of the injection device.
[0017] In some preferred embodiments, a spring in accordance with
the present invention may fulfil a dual function, namely that of
pushing the product container into its fixed seating and that of
providing the requisite force for the element which moves back to
an initial position when a dispensing operation has terminated. An
advantage of using a spring to urge or push the product container
into its fixed seat or location is that it offers an easy way of
compensating for variations in the longitudinal tolerances of
product containers. It also allows an injection device to be used
with product containers produced by different manufacturers.
Another advantage of using a spring with a dual function is that it
may replace or avoid the use of two separate springs, one of which
pushes the product container and the other of which pushes the
operating element, thereby reducing costs.
[0018] In some embodiments, the element which can be moved back to
its initial position after the dispensing operation has terminated
may prevent, e.g. lock, a movement of the output element relative
to the housing when it is in a coupled state and unlock, i.e.
release it, relative to the housing when it is in an uncoupled
state. In some preferred embodiments, this locking effect is
provided by an anti-rotation lock. In some preferred embodiments,
to effect a dispensing operation, the moveable element, which may
be a part of a coupling, is moved out of the coupled engagement for
a dispensing operation. To this end, it may be moved out of the
coupled engagement by the operating element, in which case the
operating element is operated, e.g. pushed, as a result of which
the element is moved out of the coupled engagement against the
spring force of the spring element. The element may be able to be
moved axially relative to a housing and/or the drive unit of the
injection device, but not rotate. The dispensing movement of the
output element, which may be a plunger rod and have a freely
rotatable but axially fixed flange on its end, can be effected
relative to the housing or a locating element which moves into or
is positioned in the output element. In some embodiments, the
locating element may locate in (or be received in or coupled to)
the output element so that the output element can be moved axially
relative to the locating element in and/or opposite the dispensing
direction, e.g. turned or screwed. For example, the locating
element may have an internal thread which locates in and/or
complements an external thread of the output element.
Alternatively, the output element may be longitudinally guided by
the locating element. The locating element may be secured so that
it is not able to rotate relative to the housing and may also be
secured so that it can not move axially, although this is not
necessarily the case. In some preferred embodiments, the locating
element is able to move axially relative to the housing, in which
case it is secured to the housing so that it can not move axially
when a product container has been inserted and secured on the drive
unit.
[0019] In some preferred embodiments, the output element which acts
on the product to be dispensed to dispense the product, e.g. via
the plunger, is coupled with the re-settable element in such a way
that its dispensing movement is locked when the product container
is not attached. This means that triggering is not possible if a
product container has not been inserted.
[0020] In some preferred embodiments, the output element is
unlocked and can effect a rotating movement in the state in which a
product container has not been inserted so that the output element
can be screwed back, e.g. in the proximal direction, by a rotating
movement of the output element into the drive unit if a product
container has not been inserted or if a product container holder
has been removed. In some preferred embodiments, the thread by
which the locating element locates in the output element has a
pitch which does not cause any frictional resistance of the thread
when placed under axial load. When pressure is applied to the
output element, e.g. to the flange thereof, in the proximal
direction, it is able to move easily in the proximal direction
without the user having to apply a rotating movement to the output
element. If a product container has been removed or if a product
container holder has been removed, the locating element can be
moved between a first position and a second position, and in the
first position, the output element is uncoupled from the element so
that the output element is able to move in or opposite the
dispensing direction. Providing the product container or the
product container holder has been attached to the drive unit, the
locating element is moved into its second position, thereby
preventing a rotating movement of the output element. For example,
the locating element may be moved by the product container or by
the product container holder directly or indirectly, for example by
the fixing device. The product container or the product container
holder may constitute or incorporate a part of the fixing device. A
movement out of an unsecured state into the secured state, e.g. a
rotating movement of the product container or product container
holder, in some preferred embodiments, a combined rotating-axial
movement, causes the locating element to move.
[0021] In some preferred embodiments, the locating element is
coupled with the fixing device so that when the product container
or product container holder is attached or released, it is moved
axially on or by the drive unit. The locating element may be
connected in an axially fixed arrangement to a coupling element,
such as a coupling sleeve, which is in turn able to rotate relative
to the locating element. The coupling element may be sleeve-shaped
and surround the output element or at least cooperate with the
output element so that the output element is able to move axially
relative to the coupling element but not rotate. The coupling
element may locate in a longitudinal groove of the output element.
The coupling element may be part of a transmission which transmits
the torque of the drive element to the output element. Another
element may be connected to the drive element in a fixed
torque-transmitting arrangement, such as a drive shaft which is or
can be coupled with the output element, due to the fact that the
drive shaft can be coupled with the output element via a coupling
which can be axially engaged with and released from the output
element. To this end, the coupling element and the drive shaft may
form part of the coupling, which can be coupled and uncoupled.
[0022] In some embodiments, the coupling element may also have
projections, which are moved into engagement or out of engagement
with the re-settable element depending on the desired operating
mode.
[0023] In some preferred embodiments, the spring element fulfilling
the dual function is disposed between a re-settable element and the
product container. It may be advantageous if the re-settable
element is subjected to a force acting in the proximal (rearward)
direction by the spring and the product container is subjected to a
force acting in the distal (forward) direction by the spring. The
spring element may act directly or indirectly on the product
container. In some preferred embodiments, the spring acts via one
or more parts disposed between the product container and the spring
element. For example, a retainer or retaining element may be
disposed between the product container and spring element, which
pushes on the proximal end of the product container by its distal
end. The retaining element may have an axial stop which prevents
the spring element from fully relaxing when a product container is
being removed or has been removed. For example, the stop may move
into an abutting contact with the locating element so that the
retaining element is moved axially by a distance which is limited
but long enough to compensate for longitudinal tolerances of the
product container. The retaining element may be displaceable
relative to the locating element and/or to the housing. The
arrangement may be such that the spring expends a force on the
re-settable element and also on the operating element for example,
when a product container is inserted.
[0024] In some embodiments, one or more parts, e.g. at least one
other part, may be provided between the spring and operating
element, in addition to the re-settable element, which can be moved
by the operating element and/or by the element which is re-settable
by the spring element. For example, a bearing may be provided
between the operating element and the re-settable element, which
provides a bearing for the coupling element transversely to the
longitudinal direction, and/or a threaded sleeve which can be used
to produce a rotating movement for additional parts of the
injection device, e.g. a dose display or a dose stop for the final
dose, and/or a brake to restrict the driving speed, and/or a drive
element which supplies the driving energy needed to dispense the
product. These parts may be moved in the distal direction when the
operating element is operated, for example, and in the proximal
direction during the re-setting movement of the spring element.
This being the case, the spring element also fulfils the function
of holding together axially adjoining parts or components. In some
embodiments, the spring element may also be used to couple and
uncouple various couplings, i.e. supply coupling forces.
[0025] In some embodiments, the spring fulfilling the dual function
may be a separate part or component, or it may be a part formed by
a structure or element adjoining the spring. If a separate spring
is provided, it may be made from a suitable material, e.g. plastic,
metal, etc. In some embodiments, if the spring is an integral part
of another component, the spring may be made from plastic because
it can be injection molded with the other part. An advantage of
this is that it may be possible to reduce costs. Alternatively, in
using a metal spring, the element which the spring is part of can
be cast around it. This may be done by a simple injection casting
process. For example, the spring may be integral with the
re-settable element or integral with a supporting ring which may be
provided as a separate part between the spring and retaining
element, or integral with the retaining element which pushes on the
product container and/or comprises an axial stop. Another option is
for the retaining element, spring and re-settable element to be of
an integral design.
BRIEF DESCRIPTION OF THE DRAWINGS
[0026] FIG. 1 is a cross-sectional view illustrating a proximal
(rear) part of an embodiment of an injection device in accordance
with the present invention,
[0027] FIG. 2 is a perspective view of an embodiment of a housing
part with a guide track for a bayonet lock and an inserted bayonet
sleeve,
[0028] FIG. 3 is a perspective view of the bayonet sleeve
illustrated in FIG. 2,
[0029] FIG. 4 is a perspective view of the bayonet sleeve
illustrated in FIG. 3 with a locating element inserted in it,
[0030] FIG. 5 is a perspective view of a bayonet sleeve and product
container holder, which is moved axially into a fixed
torque-transmitting engagement,
[0031] FIG. 6 is a perspective view of an output element with a
flange and spring element,
[0032] FIGS. 7A and 7B are, respectively, an exploded diagram and a
perspective view of one embodiment of a brake mechanism in
accordance with the present invention,
[0033] FIG. 8 is a perspective, exploded diagram of another
embodiment of a brake mechanism in accordance with the present
invention,
[0034] FIG. 9 is a diagram schematically plotting braking force as
a function of angular speed,
[0035] FIG. 10 is a diagram illustrating braking action as a
function of time,
[0036] FIGS. 11A and 11B are, respectively, an exploded view and a
perspective view of an embodiment of a brake mechanism in
accordance with the present invention operating on the principle of
an eddy current brake,
[0037] FIG. 12 is a perspective view of another embodiment of a
brake mechanism in accordance with the present invention operating
on the principle of a centrifugal brake,
[0038] FIG. 13 is an exploded view of another embodiment of a brake
mechanism in accordance with the present invention operating on the
principle of a fluidic brake, and
[0039] FIG. 14 is a perspective view of a brake housing from FIG.
13.
DETAILED DESCRIPTION
[0040] With regard to fastening, mounting, attaching or connecting
components of the present invention, unless specifically described
as otherwise, conventional mechanical fasteners and methods may be
used. Other appropriate fastening or attachment methods include
adhesives, welding and soldering, the latter particularly with
regard to the electrical system of the invention, if any. In
embodiments with electrical features or components, suitable
electrical components and circuitry, wires, wireless components,
chips, boards, microprocessors, inputs, outputs, displays, control
components, etc. may be used. Generally, unless otherwise
indicated, the materials for making embodiments of the invention
and/or components thereof may be selected from appropriate
materials such as metal, metallic alloys, ceramics, plastics, etc.
Unless otherwise indicated specifically or by context, positional
terms (e.g., up, down, front, rear, distal, proximal, etc.) are
descriptive not limiting. Same reference numbers are used to denote
same parts or components.
[0041] The injection device illustrated in FIG. 1 comprises a drive
unit, which, in some embodiments, can be used more than once, and a
product container 27 connected to it, which is accommodated in a
sleeve-shaped product container holder 16 which can be used
multiple times, for example, and which can be secured to the drive
unit with the aid of the product container holder 16. The product
container 27 can be removed from the injection device after it is
empty, disposed of and replaced with a new one. With a view to
simplifying the manufacturing and assembly processes, the housing
12 is of a multi-part design comprising housing elements 12a, 12b
connected to or inserted in it, although in principle, the housing
could also comprise a single part. The product container 16 is
attached to the drive unit by a bayonet fitting, which is formed by
the housing 12, product container holder 16 and sleeve 50. The
product container holder 16 is covered by a cap 31, which is fitted
on the housing 12, and can be removed in preparation for using the
injection device and then fitted back on it.
[0042] FIGS. 2 to 5 illustrate elements of the fixing device
provided in the exemplary form of a bayonet fitting. The product
container holder 16 has a cam 16c extending radially outwardly and
at its proximal (rear) end face is designed so that it can be
connected in a positive fit, i.e. in a fixed torque-transmitting
fit, to the distal (forward) end face of the sleeve 50, as
illustrated in FIG. 5 where housing part 12a has been omitted for
illustration purposes. The sleeve 50 has at least one cam 50c
extending radially outwardly, which forms a part of a cam (which
may be thought of as comprising cam elements 16c, 50c) for the
fixing device. The cam 50c locates or is positioned in a guide
track 12e formed in the housing 12, e.g. in housing part 12a, which
has at least one inclined surface 12g. When the sleeve 50 is moved
in rotation, the sleeve 50 moves axially relative to the housing
part 12a as well as moving in rotation, due to the locating cam
50c. As will be described below, the axial movement of the sleeve
50 results in various advantageous effects.
[0043] To fit the product container 27 on the drive unit, it may be
introduced into the product container holder 16 via the proximal
end. The product container holder 16 is then snap-fitted onto the
sleeve 50 by an axial movement resulting in a fixed
torque-transmitting fit (FIG. 5), so that the cams 16c are inserted
through the opening 12f (FIG. 2) into the guide track 12e. FIG. 2
illustrates the bayonet fitting in a locked state without the
product container holder 16. In an unlocked state in which the cams
50c are disposed in the region of, and axially flush with the
openings 12f, the product container holder 16 can be push-fitted.
The cams 16c and 50c then lie one against the other and form a
common cam (FIG. 5). A rotation of the product container holder 16
causes the sleeve 50 to be driven. Due to the inclined faces 12g,
the sleeve 50 and the product container holder 16 are also moved
axially. At the end of the rotation, i.e. on reaching the locked
position, the common cam (comprising cam elements 16c, 50c) is
disposed in the region 12h of the guide track 12e in which the two
cams 16c and 50c are axially clamped together by the sides of the
guide track 12e. To this end, the axial width of the guide track in
the region 12h is approximately as wide as that of the joint cams
16c, 50c.
[0044] As illustrated in FIG. 4, a guide sleeve 26 is accommodated
in the sleeve 50, which may also be thought of and/or referred to
as the bayonet sleeve. The guide sleeve 26 is connected to the
housing 12 so that it can not rotate but can move axially and is
connected to the bayonet sleeve 50 so that it can rotate but can
not move axially. As a result, when the bayonet sleeve 50 is moved
from the unlocked to the locked position and vice versa, the guide
sleeve 26 effects a longitudinally guided movement relative to the
housing 12.
[0045] As may be seen from FIG. 1, a threaded insert 6 is connected
and/or latched to the guide sleeve 26 so that it can not rotate or
move axially. The threaded insert 6 and guide sleeve 26 may be
thought of and/or referred to as a locating element (comprising
insert and sleeve elements 6, 26). The threaded insert 6 has an
internal thread 6a in which the external thread 2a of an output
element 2, which might also be called a plunger rod in this
example, is guided so that when the output element 2 is rotated, it
is guided by the internal thread 6a of the threaded insert 6 in the
proximal direction or in the distal, i.e. opposite, direction, as
it is screwed, depending on the direction of rotation.
[0046] On its external face, the output element 2 has a thread 2a,
which is interrupted by two grooves 2b extending in the axial
direction lying opposite one another on the circumference. A
coupling sleeve 5 constituting part of a transmission (comprising
elements 7, K2, 5) has two projections 5a, 5b directed radially
inwardly lying opposite one another on its distal end which project
into the grooves 2b of the output element 2. The coupling sleeve 5
is connected to the locating element so that it can rotate but is
not able to move axially. Accordingly, the output element 2 is
locked to prevent it from rotating relative to the coupling sleeve
5 but is able to move axially relative to the coupling sleeve 5
when it is rotated relative to the locating element. The coupling
sleeve 5 is not able to move axially expect for when the product
container 27 is being replaced.
[0047] A drive shaft 7 provided at the proximal end of the
injection device and forming part of the transmission has teeth 7a
extending radially inwardly which constitute a coupling element of
the coupling K2. When operated, i.e. when an operating element 15
is pushed in the distal (forward or injection) direction, the drive
shaft 7 and as a result also the teeth 7a are moved in the distal
direction, as result of which the teeth 7a locate in the proximal
end of the coupling sleeve 5 and establish a fixed
torque-transmitting, positive connection.
[0048] A spring element or drive spring 3, which may be provided in
the form of a helical spring or clock spring, is connected to the
housing 12 by one end via a spring sleeve 8 on the external face of
the spring 3. The spring sleeve 8 is prevented from rotating
relative to the housing 12 but is able to move axially. At the
other end, the drive spring 3 is connected to the drive shaft 7. As
a result, energy stored in the spring 3 can be output as a rotating
movement of the drive shaft 7 relative to the housing 12. To
dispense a product, the energy of the spring element 3 is
transmitted via the transmission element in the form of a rotating
movement to the output element so that the latter is screwed
relative to the locating element in the distal direction, i.e. in
the dispensing direction, and pushes the plunger 28, causing the
product to be dispensed from the product container 27.
[0049] To set a product dose to be administered, a user can rotate
the dose setting element 9 provided in the form of a dose setting
button, which is axially fixed relative to the housing 12. The dose
setting element 9 is coupled with a coupling element 10 via the
coupling K3 so that it is prevented from rotating. The coupling K3
is formed by webs or grooves or teeth of the dose setting button 9,
which co-operate in a positive fit with webs or grooves or teeth of
the coupling disc 10 to establish a coupling which can be released
by a movement of the coupling element 10 in the distal direction.
The coupling element 10 can be moved and thus released by operating
the operating element 15. When in a state of not being operated,
the coupling K3 is held in a coupled state and the coupling K2 in
an uncoupled state by a spring element 19, which pushes the drive
shaft 7 in the proximal (rear or rearward) direction. During the
dose setting operation, the coupling K3 is coupled, i.e. a rotating
movement of the dose setting button 9 is transmitted to the
coupling element 10. The coupling element 10 is connected to the
drive shaft 7 so that it can not move axially and can not rotate
and could also be an integral part of the drive shaft 7. The
rotating movement of the dose setting element 9 is not transmitted
to the coupling sleeve 5 because the coupling K2 is uncoupled.
[0050] When the drive shaft 7 is rotated, the drive spring 3
connected to the drive shaft 7 is tensed. To prevent the dose
setting button 9 from being turned back due to the drive spring 3
as it is tensed during the setting operation, a ratchet 11 or a
ratchet mechanism, which may comprise a ratchet spring 11a, e.g.
for clamping retaining elements, may be provided between the
housing 12 of the injection device, the components of which might,
for example, be a mechanical holder 12a and a mechanical holder 12b
and the dose setting button 9. The ratchet mechanism may be
designed so that a rotation and/or a tensing of the drive spring 3
is possible in only one direction. In some preferred embodiments,
however, the ratchet mechanism is designed so that the rotating
action is possible in both directions, e.g. tensing and relaxing of
the drive spring 3. Due to the fact of being able to rotate in both
directions, a product dose can be both increased and reduced when
setting the product dose. A currently set product dose can be read
through the window 12d of a display barrel 4.
[0051] The rotating movement of the drive shaft 7 is also
transmitted to the threaded sleeve 13, which is connected to the
drive shaft 7 so that it is not able to move axially or rotate and
may also be an integral part of it. The threaded sleeve 13 has at
least one groove on its external circumference 13a in which at
least one web 4a of the display barrel 4 locates so that a rotating
movement of the threaded sleeve 13 is transmitted to the display
barrel 4 by the anti-rotation coupling, permitting an axial
relative movement between the display barrel 4 and threaded sleeve
13. The display barrel 4 has a thread 4b on its external face which
locates in an internal thread 12c of the housing part 12b so that
the display barrel 4 is moved due to a rotating movement in the
axial direction relative to the housing 12, e.g. in the distal
direction. In some preferred embodiments, the display barrel 4
moves in the distal direction of the injection device (towards the
left in FIG. 1) during the process of setting and priming the dose
by rotating the dose setting button 9. A marking may be provided on
the external face of the display barrel 4, such as print, a dose
display or a scale, which can be read through an opening or a
window 12d in the housing 12b of the injection device, and the
marking of the display barrel 4 is moved relative to the window
12d. The display barrel 4 has a rotation stop on its distal end
acting in the circumferential direction which moves into an
abutting contact with a co-operating complementary stop disposed on
the housing part 12a on reaching the maximum dose. The
complementary stop is formed by a terminal end of an annular gap of
the housing part 12a. An advantage of using a stop which acts in
the circumferential direction rather than an axial stop is that the
forces acting on the stop are weaker. The display barrel 4 also has
another rotation stop on its proximal end acting in the
circumferential direction, which moves into an abutting contact
with a co-operating complementary stop on the housing 12b on
reaching a minimum dose. The complementary stop is formed by the
proximal end of the thread 12c.
[0052] Once the dose has been set and the drive spring 3 primed by
rotating the dose setting button 9, the setting operation is
complete. In some preferred embodiments, the dose is primed as the
spring 3 is tensed. To correct or adjust the dose, the dose setting
button 9 simply has to be rotated in the opposite direction, e.g.
to reduce a dose which might have been set too high. In some
embodiments, the ratchet 11 may be designed as illustrated in FIGS.
14 and 15 of patent application PCT/CH2007/000243 and/or US
Publication 2009/0254035, the teachings of which are incorporated
herein by reference.
[0053] During the dispensing process, which is triggered by
depressing the push button 15, the display barrel 4 is rotated back
in the opposite direction and is moved back in the proximal
direction due to the thread engagement with the internal thread 12c
of the injection device (to the right in FIG. 1). As this happens,
it reaches a stop of the display barrel 4 acting in the
circumferential direction on the housing of the injection device,
e.g. on the housing part 12b. In an unbraked dispensing movement in
which the threaded rod 2 is moved in the distal direction without
any opposing force, e.g. when no product container has been
inserted, this operation may result in too high a strain and, in an
extreme situation, deformation or even damage to the display barrel
4 or co-operating part 12b. A brake mechanism (e.g. comprising
brake elements, e.g. shoe halves and disc 17, 18) acting on the
driving movement is therefore provided, which will be described
below.
[0054] The coupling K1, comprising the coupling element acting as a
lock sleeve 14 and the coupling sleeve 5, is used to couple the
coupling sleeve 5 with the housing 12 so that it can not rotate in
specific operating modes or to release it to permit a rotation
relative to the housing 12. The coupling K1 is uncoupled when the
product container 27 is being replaced to enable the output element
2 to be pushed back or screwed in the proximal direction again and
to enable the output element 2 to be screwed in the distal
direction while product is being dispensed. The coupling K1 is
coupled when the product container is attached to the drive unit
and the operating element 15 is not being operated. The coupling K1
is provided in the form of teeth on the external face of the
coupling sleeve 5, which mesh in teeth on the internal face of the
lock sleeve 14. As a result, the coupling sleeve 5 is prevented
from rotating relative to the lock sleeve 14. The lock sleeve 14 is
mounted in the injection device so that it can not rotate but can
move axially relative to the housing 12 and the coupling sleeve
5.
[0055] During a dispensing operation, the threaded sleeve 13 is
moved in the distal (forward or injection or delivery) direction by
operating the operating element 15. As this happens, the threaded
sleeve 13 pushes on the bearing 29, which is provided in the form
of a ball bearing in this example but may also be a simple slide
bearing, so that the bearing 29 pushes against the lock sleeve 14,
thereby moving it in the distal direction for a dispensing
operation, and holds it in a distal position during a dispensing
operation. The coupling element 14 is therefore disposed distally
of the projections of the coupling sleeve 5 for the coupling K1. As
a result, the coupling K1 remains uncoupled for the duration of the
dispensing operation.
[0056] When the operating element 15 is operated, the couplings K1,
K2 and K3 operate as follows. By depressing the push button 15
seated on the coupling element 10 and/or drive shaft 7, the
coupling element 10 is pushed in the distal direction together with
the push button 15 and the drive shaft 7. As a result, the coupling
K2 is coupled so that the drive shaft 7 is prevented from rotating
relative to the coupling sleeve 5. The coupling K1 is then
uncoupled due to the movement of the lock sleeve 14, against which
the threaded sleeve 13 connected to the drive shaft 7 pushes via
the axially displaceable bearing 29. Alternatively, the couplings
K1 and K2 may be connected in the reverse sequence.
[0057] Once K2 is coupled and K1 is uncoupled, the coupling K3 is
also uncoupled due to the movement of the coupling element 10
relative to the dose setting button 9. The coupling element 10,
which is connected to the drive shaft 7, is able to rotate relative
to the housing 12 once the coupling K3 is uncoupled. The energy or
force stored in the drive spring 3 during priming can be
transmitted to the drive shaft 7. Accordingly, a torque is applied
to the drive shaft 7, which is transmitted by the coupled coupling
K2 to the coupling sleeve 5, which rotates in unison with the drive
shaft 7 and transmits this rotating movement to the output element
2, which is coupled with the coupling sleeve 5 so that it can not
rotate. The output element 2, provided in the form of a threaded
rod in this example, converts the rotating movement into an axial
movement in the distal direction due to the thread engagement 2a,
6a with the locating element (comprising elements 6, 26), so that
the flange 1 provided on the distal end of the threaded rod 2,
which may also be construed as part of the output element, is moved
in the distal direction of the injection device.
[0058] Since, during the product dispensing operation, the threaded
sleeve 13 moves in the direction opposite that in which it moves
during priming, the display barrel 4 likewise moves in the
direction opposite that of the priming operation.
[0059] In the normal situation, i.e. when a pre-set product dose
has been fully dispensed, the dispensing operation and the movement
of the output element 2 in the distal direction continues until the
display barrel 4 makes contact with the above-mentioned stop acting
in the circumferential direction. In some embodiments, this happens
when the value which can be read through the window 12d has been
rotated back to 0.
[0060] In the situation in which the user of the device releases
the operating element 15 as the product is being dispensed, the
couplings couple in the order which is the reverse of that in which
they uncoupled or coupled during operation. The product dispensing
operation is interrupted, as a result of which the value may be
seen through the window 12d represents the amount still to be
dispensed had the pre-set dose been fully dispensed. The product
dispensing operation can be continued by depressing the operating
element 15 again, and dispensing can be stopped again by releasing
the operating element 15 or the user can wait until the product has
been fully dispensed.
[0061] In the situation in which the product container contains
less product than the maximum dose indicated on the display barrel,
the injection device based on this example has an additional device
for limiting the maximum dose which can be set for the last time,
to prevent the possibility of a bigger product dose being set than
that which is still in the container. To this end, a traveller 30
is provided, which at least partially surrounds the coupling sleeve
5 and locates with the coupling sleeve 5 in such a way that the
traveller 30 is not able to rotate relative to the coupling sleeve
5 but is able to move axially. The traveller 30 also locates or is
positioned by a thread on its external circumference that engages
with an internal thread of the threaded sleeve 13. This arrangement
causes an axial movement of the traveller 30 when there is a
relative rotation between the threaded sleeve 13 and coupling
sleeve 5, and when there is no relative rotation the traveller 30
does not effect an axial movement. When setting a product dose, the
threaded sleeve 13 turns relative to the coupling sleeve 5 so that
the traveller 30 moves in the proximal direction. During
dispensing, on the other hand, no relative movement takes place
between the coupling sleeve 5 and threaded sleeve 13 due to the
coupled engagement of the coupling K2. Accordingly, the traveller
does not move. After setting doses and dispensing product several
times, the traveller 30 moves into an abutting contact with the
drive shaft 7, so that it is no longer possible to increase the
dose, even if the display would actually permit this.
[0062] The user can replace the product container 27 with a new
one. To this end, the product container holder 16 may be removed by
rotating the drive unit relative to the housing 12. As the product
container 27 is moved from the secured position into the
non-secured position, e.g. as the bayonet fitting is released, the
locating element is moved together with the output element 2 and
the coupling sleeve 5 in the distal direction relative to the
housing 12 and to the coupling element 14, thereby releasing the
coupling K1. The projections of the coupling sleeve 5 pointing
radially outwardly to establish the coupling K1 are now disposed
distally of the coupling element 14. The output element 2 can now
be screwed into the drive unit with a relatively slight force
acting in the proximal direction because the thread of the output
element is not retained by friction. As the output element 2 is
screwed back, the coupling sleeve 5 is turned relative to the
threaded sleeve 13 and so in the direction opposite that during
product dispensing, causing the traveller 30 to be pushed back in
the distal direction again. The screwing-back operation may take
place against the force of a spring element, at least across a part
of the total distance, which tries to push the output element in
the distal direction, for example. The spring element may act or be
disposed between the output element 2 and the drive shaft 7 for
example. Other possible spring elements will be described below
specifically with reference to FIG. 6. It is generally preferred if
the force of such a spring element is weaker than the force needed
to produce an interaction via the plunger from the output element 2
onto the product.
[0063] Also during the process of removing the product container
27, the retaining element 25 used to secure the product container
27 in the product container holder 16 is pushed in the distal
direction by the spring 19 until it makes contact with the locating
element 6, 26. This contact prevents the spring 19 from fully
relaxing when the product container 27 is removed. This is of
advantage because the spring 19 should be able to apply sufficient
force to hold the coupling K3 in a coupled engagement even when a
product container 27 has been removed.
[0064] By virtue of another aspect, a spring-mounted flange may be
used, as illustrated in FIG. 6 for example.
[0065] After replacing the product container 27, e.g. an ampoule,
capped vial or the like, the user is prompted to proceed with
priming, as may be described in operating instructions. This is
useful on the one hand because there may be air in the product
container 27 and on the other hand because the output element 2 may
have been previously pushed fully into the drive unit and a certain
amount of clearance may have been created between the plunger 28
and the flange 1 due to the different level to which the product
container 27 is filled.
[0066] FIG. 6 illustrates an output element 2 with a flange 1
attached to its front or distal end, which is non-displaceably
connected to the threaded rod. Disposed between the flange 1 and
the threaded insert 6 illustrated in FIG. 6 is a spring element 38,
which may be provided in the form of resilient arms 38a extending
out at an angle, for example. These resilient arms 38a may be
secured to the flange 1 or/and to the threaded insert 6. Another
option would be to injection mold a suitable elastomer onto the
flange 1 or/and onto the threaded insert 6. After a new product
container 27 has been inserted, a clearance may occur between the
flange 1 and the plunger 28, which may be attributable to a
difference in the level to which product containers 27 have been
filled when full, given that they have a certain tolerance.
[0067] After pushing in the flange 1 connected to the threaded rod
2, the flange 1 based on the embodiment illustrated in FIG. 1 lies
directly against the threaded insert 6.
[0068] In the embodiment illustrated in FIG. 6, the at least one
spring element 38 has pushed the flange 1 away from the threaded
insert 6 in the distal direction by a predefined distance. This
means that when a product container 27 has been inserted or while a
product container 27 is being inserted, the flange 1 will move into
contact with the proximal end of the plunger 28, even if the
plunger 28 is pushed into the product container 27 by differing
distances caused by manufacturing tolerances of different product
containers. Conventional means for eliminating the clearance
between the flange 1 and plunger 28 are therefore no longer
absolutely necessary and may even be dispensed with, for
example.
[0069] As may be seen from FIG. 1, the injection device, e.g. the
drive unit, comprises a brake (which may be thought of as
comprising brake elements or components 17, 18) which decelerates a
rotating part, in this example the transmission element or/and the
driving movement. If conventional injection devices are used
incorrectly, i.e. if no product container has been inserted, but
the device is nevertheless operated, there is a risk of placing too
high a strain on or even damaging the components of the injection
device. When a product container 27 is inserted, the forces and
movements which occur are damped by the viscosity of the product
during the product dispensing operation. In the absence of a
product container, there is no such damping effect. It is the brake
in accordance with the present invention which is used for this
purpose, thereby preventing excessive strain.
[0070] FIGS. 7A, 7B and 8 are diagrams on a larger scale
illustrating embodiments of a brake mechanism suitable for the
device illustrated in FIG. 1, e.g. a first and second embodiment,
respectively, each of which operates in a similar manner. The first
embodiment illustrated in FIGS. 7A, 7B has two brake shoe halves 17
latched to one another so that they can not rotate and so that they
can also not move axially, which have profiled portions directed
toward one another, between which an annular gap is formed in which
a brake disc 18 is accommodated. The annular gap is of a defined
width and, in an alternative arrangement, the brake shoe halves
could move axially relative to one another. The brake shoe 17 could
be of an integral design. The brake disc 18 is accommodated so that
it can not rotate relative to the housing 12 but can move axially,
due to the profiled external circumferential surface of the brake
disc locating in a profiled inner circumferential surface of the
housing part 12b. At least one brake shoe half 17 or the entire
brake shoe is mounted at least so that it can not rotate in the
drive train or transmission element. The sleeve-shaped brake shoe
17 has projections pointing radially inwardly, which locate in a
matching profile of the drive sleeve 7. The brake disc 18 is able
to move between the brake shoe halves 17. The brake disc 18 is
mounted so that it can not rotate, e.g. is guided in a groove, and
so that it is able to move axially in the injection device or
housing part 12b. The brake disc 18 is toothed on the top and
bottom face with teeth 18a, 18b on the end face projecting
circumferentially in both directions and having an identical or
different tooth height ZH, and is mounted or displaceably clamped
between the threaded sleeve 13 and the brake shoe 17, e.g. with a
small clearance of approximately a tooth size or tooth height ZH or
bigger, the latter having co-operating complementary teeth 13b
respectively 17a, e.g. with a corresponding or identical tooth
height ZH.
[0071] Due to the fixed torque-transmitting connection between the
transmission element (which, again, may be thought of and/or
referred to as comprising elements 7, K2, 5) during a dispensing
operation or when what may be thought of and/or referred to as
"firing blank," i.e. when no product container has been inserted,
the brake shoe 17 is moved in rotation relative to the brake disc
18. When this happens, the disposition of the brake shoe teeth 17a,
17b ensure that the brake disc 18 oscillates axially between the
threaded sleeve 13 and the brake shoe 17. As a result, the distal
teeth 18a and proximal teeth 18b of the brake disc 18 move
alternately into contact with the co-operating complementary teeth
17b and 17a. Due to one or more of the resultant friction, elastic
deformation and the oscillating mass, a corresponding loss occurs,
thereby limiting the maximum angular speed .omega. of the rotating
parts 13 and 17.
[0072] The embodiment illustrated in FIG. 8 operates on a similar
principle, the difference being that one of the two brake shoe
halves and/or its end-face tooth profile is formed by the
transmission element or the threaded sleeve 13 connected to the
transmission element so that it cannot rotate. A fixed, defined
distance may be provided between the profiles 17a and 13b, or
alternatively a variable distance, because the brake shoe half 17
is able to move axially relative to the threaded sleeve 13. Due to
the spring 19, the profiles 13b and 17a can be pushed toward one
another so that they move into a meshing contact with the profiles
18a and 18b.
[0073] Due to the vibration or oscillation of the brake disc 18
between the threaded sleeve 13 and brake shoe 18 which increases
with the angular velocity .omega., the braking force increases
disproportionately as the angular velocity .omega. increases, so
that the curve BS of braking forces schematically illustrated in
FIG. 9 can be achieved.
[0074] FIG. 9 is a schematic illustration plotting the curve of the
braking force which can be achieved by a brake mechanism in
accordance with the present invention, from which it may be seen
that the braking force rises to an increasing degree with the
angular or rotational velocity .omega.. In some preferred
embodiments, the braking force is relatively low or zero up to the
maximum permissible angular velocity .omega..sub.max and rises
sharply with effect from the maximum permissible angular velocity
.omega..sub.max.
[0075] FIG. 10 illustrates the angle of rotation of the display
barrel 4 as a function of time, which is able to effect three full
revolutions (3.times.360.degree.) in the embodiments illustrated as
an example. As may be seen from FIG. 10, the display barrel 4 has
completed three full revolutions after the time t.sub.non-braked,
which is shorter than the time t.sub.invention in the case of a
decelerated rotating movement of the display barrel 4 during which
the angle of rotation increases linearly as a function of time.
[0076] Due to the braking force generated by the oscillating brake
disc 18, the maximum possible angular velocity .omega..sub.max of a
dispensing movement can be reduced or limited so that the
backward-rotating display barrel 4 is able to move into an abutting
contact with the stop acting in the circumferential direction or
the housing part 12b at only a maximum speed predefined by the
brake. If the brake is designed accordingly, the maximum possible
contact speed of the display barrel 4 is so low that there is
little chance of deformation or damage occurring due to the impact.
Other brake mechanisms may also be used as an alternative to a
brake disc 18 oscillating between the threaded sleeve 13 and brake
shoe 17.
[0077] For example, as an alternative or in addition, the brake may
be based on another embodiment in the form of a centrifugal brake
as illustrated in FIG. 12. In this case outwardly displaceable
brake shoes 41 are mounted on the transmission element or/and the
drive shaft 7 and/or another part which rotates with the drive
shaft 7, for example the coupling element 10, the threaded sleeve
13 or the display barrel 4, which have a mass and which effect the
same rotation as the rotating part. The brake shoes 41 may, but
need not necessarily, be inwardly or outwardly biased by a spring.
The brake shoes may be pivoted or moved radially outwardly by the
centrifugal force to move into a braking engagement with a sleeve
42, for example the housing 12. In this embodiment, pins 40 or
fasteners extending radially outwardly are provided, the ends of
which are provided with brake pads 41 biased by the spring, for
example. When the rotation speed of the non-braked or only
partially braked rotating element is sufficiently high, the brake
pads 41 are moved radially outwardly by the centrifugal force,
optionally also assisted by the spring-biased support, and can move
into contact with an outer static sleeve 42, thereby producing the
desired braking effect due to friction. The outer static sleeve may
also be formed by the housing 12 or housing part 12b.
[0078] In another embodiment illustrated in FIGS. 11A and 11B, the
brake may be provided in the form of an eddy current brake 20, in
which case a brake disc 21 may be connected to a rotating part
which has to be decelerated, for example the transmission element,
drive shaft 7, threaded sleeve 13 or display barrel 4, and the
elements interacting with the brake disc may be connected to the
housing or an element fixedly disposed on the housing or to an
element rotating relative to the brake disc.
[0079] In some preferred embodiments, the brake disc 21 is made
from a good electrical conductor, such as pure aluminium or copper,
for example. Rare earth alloys may be used as the material for the
axially magnetised magnets 22, neodymium for example. The permanent
magnetic field may be linked by a magnet yoke 23 made from iron to
the air gap, where it extends through the brake disc 21 as
vertically as possible. The braking force is created by the surface
and flow density in the air gap and the rated current in the brake
disc 21, for which purpose the surface should be as large as
possible, the air gap should be as small as possible and the disc
thickness should be as big as possible. The braking torque occurs
over the averaged radius (working radius). Brakes may be designed
with several magnet systems which act on a disc 21.
[0080] The usual approximation calculations are used to calculate
the current density, braking power and hence braking torque of an
eddy current brake. Leaving aside the effect of the air gap, it is
assumed that there will be a standard cylindrical magnetic flow and
it is stipulated as a condition that the pole diameter should be
sufficiently small compared with the radius of the disc 21. At high
speeds, the approximation is inaccurate, among other reasons
because the magnetic fields caused by the eddy currents cause a not
inconsiderable feedback and hence non-linearity.
[0081] In some preferred embodiments, the magnets 22 and the magnet
yoke 23 are connected to the housing 12 of the injection device or
the housing part 12b or another non-rotating part to be able to
generate the desired eddy current braking effect of the brake disc
21.
[0082] In another embodiment illustrated in FIGS. 13 and 14, the
brake may be provided in the form of a fluidic or hydrodynamic
brake. If a standard fluid is used as the braking medium, the
linear braking curve FB indicated in FIG. 4 can be obtained for the
eddy current brake. However, if the intention is to achieve a
braking force which rises more sharply as a function of angular
velocity .omega., so-called non-Newtonian fluids may be used, as a
result of which, unlike a Newtonian fluid, the viscosity does not
remain constant but increases when a shearing force acting on the
fluid is increased, which is the case as the speed increases. These
are what are known as anomalous viscous fluids.
[0083] In the case of the fluidic brake, the braking force is
generated by two fluid surfaces moving against one another. In
particular, the braking force is generated by a fluid volume which
is sheared by a relative movement. The shearing stresses which
occur during such movements correspond to the braking force. The
volume is provided in the form of a chamber split into two parts
45a, 46a, in which the fluid is disposed. One chamber part 46a is
disposed in a rotating part 46 and the other chamber 45a is
disposed in a part 45 relative to which the rotating part 46 is
able to rotate. The part 46 may be connected so as to rotate in
unison with the drive shaft 7 or to the transmission element or
another part which rotates when product is being dispensed. The
part 45 rotates in unison with at least the housing 12 or a
stationary part on the housing. Furthermore, the part 45 may be
able to move axially or may be axially immobile relative to the
housing 12. The sleeve-shaped part 45 may be thought of and/or
referred to as a brake housing and the part 46 mounted in the
sleeve 45 as a brake shaft. When the brake is in the assembled
state, the fluid chamber halves 46a distributed axially around the
external circumference of the brake shaft are axially on a level
with the fluid chamber halves 45a distributed around the internal
circumference of the brake housing. More, the same number or fewer
fluid chamber halves 45a may be provided than 46a. In the assembled
state, a slim gap is disposed between the internal diameter of the
brake housing 45 and the external diameter of the brake shaft 46 in
the region of each of the fluid chamber halves 45a, 46a, which may
be dimensioned so that fluid is conveyed into the gap or no fluid
or virtually no fluid is conveyed into the gap when the brake shaft
46 is rotating relative to the brake housing 45. The brake housing
45 may be axially sealed at both ends with sliding seal elements 47
so that no fluid is able to escape from the brake. The seal
elements 47 may be provided in the form of a lid. The lid may be
provided as a separate part or serve as the coupling shaft, for
example.
[0084] Embodiments of the present invention, including preferred
embodiments, have been presented for the purpose of illustration
and description. They are not intended to be exhaustive or to limit
the invention to the precise forms and steps disclosed. The
embodiments were chosen and described to illustrate the principles
of the invention and the practical application thereof, and to
enable one of ordinary skill in the art to utilize the invention in
various embodiments and with various modifications as are suited to
the particular use contemplated. All such modifications and
variations are within the scope of the invention as determined by
the appended claims when interpreted in accordance with the breadth
they are fairly, legally, and equitably entitled.
* * * * *