U.S. patent application number 11/049503 was filed with the patent office on 2005-06-16 for needleless hypodermic injection system, application device and medication cartridge therefor.
Invention is credited to Bandau, Dirk, Bevan Kirby Meacham, George, Bruntrup, Otto, Engelhardt, Horst, Gliewe, Christian, Haar, Hans-Peter, Ihle, Guenter Franz, List, Hans, Popp, Konrad Joseph, Riemensperger, Ulrich Josef, Thos, Bruno Robert.
Application Number | 20050131342 11/049503 |
Document ID | / |
Family ID | 23063444 |
Filed Date | 2005-06-16 |
United States Patent
Application |
20050131342 |
Kind Code |
A1 |
Haar, Hans-Peter ; et
al. |
June 16, 2005 |
Needleless hypodermic injection system, application device and
medication cartridge therefor
Abstract
A needleless hypodermic injection system for injecting a liquid
medication, which system comprises a disposable cartridge which
contains a medication and which comprises a propellant and an
igniter, and a reusable application device which comprises a
pressure chamber for receiving the medication cartridge, actuation
means including an ignition system and means for ensuring
reliability and safety of the system. The reusable application
device comprises: (a) a housing including a fist housing section
and a second housing section which are adapted to be assembled
together by a screwing operation, the first housing section
comprising a front part having an injection outlet and a chamber
adapted to receive a the cartridge contains the medication to be
injected and also contains a propellant and an igniter, and (b)
means for selectively activating said igniter of said cartridge
when predetermined conditions are fulfilled.
Inventors: |
Haar, Hans-Peter; (Wiesloch,
DE) ; Bevan Kirby Meacham, George; (Shaker Heights,
OH) ; Popp, Konrad Joseph; (Augsburg, DE) ;
Bruntrup, Otto; (Munich, DE) ; Riemensperger, Ulrich
Josef; (Edenried-Aichach, DE) ; Ihle, Guenter
Franz; (Mauer, DE) ; Thos, Bruno Robert;
(Quierschied, DE) ; List, Hans; (Hesseneck,
DE) ; Bandau, Dirk; (Ottersheim, DE) ;
Engelhardt, Horst; (Neuhofen, DE) ; Gliewe,
Christian; (Lampertheim, DE) |
Correspondence
Address: |
HOFFMANN-LA ROCHE INC.
PATENT LAW DEPARTMENT
340 KINGSLAND STREET
NUTLEY
NJ
07110
|
Family ID: |
23063444 |
Appl. No.: |
11/049503 |
Filed: |
February 2, 2005 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
11049503 |
Feb 2, 2005 |
|
|
|
10101400 |
Mar 19, 2002 |
|
|
|
60278042 |
Mar 22, 2001 |
|
|
|
Current U.S.
Class: |
604/68 |
Current CPC
Class: |
A61M 5/2425 20130101;
A61M 2005/3118 20130101; A61M 5/3129 20130101; A61M 5/2046
20130101; A61M 5/30 20130101; A61M 2205/583 20130101; A61M 5/5086
20130101; A61M 2005/312 20130101; A61M 2205/582 20130101; A61M
2005/2013 20130101 |
Class at
Publication: |
604/068 |
International
Class: |
A61M 005/30 |
Claims
1. An application device for needleless hypodermic injection of a
liquid medication said application device comprising a) a housing
having a length axis and an outer contact surface which is adapted
to be applied on a skin surface through which an injection is to be
applied; b) said housing containing ejection means causing ejection
of said liquid medication in order to perform an injection and
actuator means for activating said ejection means; and c) position
detecting means for detecting whether said contact surface of said
housing exerts a predetermined pressure on said skin surface and
whether at the same time said length axis of said housing is
positioned substantially normal to said skin surface, the
distribution of said pressure over the area of said contact surface
being substantially uniform, said means for detecting enabling said
actuator means when the latter conditions are satisfied.
2. A device according to claim 1, wherein the ejection means
comprise a propellant and means for its ignition.
3. A device according to claim 1, wherein said position detecting
means exclusively comprise mechanical and electro-mechanical means,
but no electronic means sensitive to electrical noise or other
perturbating electrical signals.
4. A device according to claim 1, wherein said position detecting
means comprise a first switch adapted to be mechanically actuated
by a movable part of said position detecting means to establish an
electrical connection when said position detecting means senses
application of the contact surface of the housing on said skin
surface with a predetermined pressure applied on the skin
surface.
5. A device according to claim 1, wherein said housing is so
configured and dimensioned that it is adapted to be held and used
by a user with only one hand.
6. A device according to claim 1, further comprising means
providing a visual or audible indication to the user when said
actuator means is enabled.
7. A device according to claim 1, wherein the position detecting
means comprise a purely mechanical object sensor, and a first
switch adapted to be mechanically actuated by a movable part of the
position detecting means to establish an electrical connection when
said object sensor senses application of the contact surface of the
housing on a body part.
8. A reusable application device for needleless hypodermic
injection of a liquid medication said application device comprising
a) a housing having a length axis and an outer contact surface
which is adapted to be applied on a skin surface through which an
injection is to be applied wherein the housing comprises a first
section and a second section which are adapted to be connected with
each other to form a housing assembly, said first housing section
comprising a chamber for receiving a cartridge containing a
medication unit which contains a liquid medication, said first
housing section having a symmetry axis which extends along its
length and a front part having the outer contact surface which is
adapted to be applied on a skin surface, said contact surface
having an opening through which liquid medication ejected from said
cartridge can pass and be injected through said skin surface; b)
said housing containing ejection means causing ejection of said
liquid medication in order to perform an injection and actuator
means for activating said ejection means wherein a first part of
the ejection means is contained in said cartridge and a second part
of said ejection means is contained in said second housing section;
c) assembly detecting means which reach a first predetermined state
when said first housing section is properly and completely
assembled with said second housing section to form said housing
assembly, said assembly detecting means being located within said
housing assembly; d) position detecting means for detecting whether
said contact surface of said housing exerts a predetermined
pressure on said skin surface and whether at the same time said
length axis of said housing is positioned substantially normal to
said skin surface, the distribution of aid pressure overt the area
of said contact surface being substantially uniform, said means for
detecting enabling said actuator means when the latter conditions
are satisfied wherein the position detecting means are located in
part within said first housing section and in part in said section
housing section, said position detecting means reaching a second
predetermined state when the following conditions are
simultaneously satisfied by the relative position of said housing
assembly with respect to said skin surface, d.2) said contact
surface of said first section exerts a predetermined pressure on
said skin surface, the distribution of said pressure over the area
of said contact surface being substantially uniform, and d.3) said
symmetry axis of said first section is positioned substantially
normal to said skin surface; and e) the actuator means are normally
disabled and become operable only upon being enabled by a
combination of predetermined effects provided by said assembly
detecting means after they reach said first predetermined state,
and said position detecting means when they reach said second
predetermined state.
9. A device according to claim 8, wherein said second housing
section comprises means which are adapted to cooperate with a
corresponding part of said first housing section for clamping with
a predetermined preload and for hermetically closing a cartridge
inserted into said cartridge receiving chamber.
10. A device according to claim 8, wherein said first housing
section and said second housing section are so shaped, dimensioned
and configured that proper and complete assembly therefore is
accurately defined and recognizable by visual and tactile
inspection.
11. A device according to claim 8, wherein said first housing
section and said second housing section are adapted to be assembled
together by assembling steps which include a screwing
operation.
12. A device according to claim 8, wherein injection is caused by
an electrical circuit comprising a battery, a first switch a second
switch adapted to be actuated by a user, interconnection
conductors, and two electrical terminals which correspond to
respective terminals of an igniter, said electrical circuit being
so configured that electrical current can flow from the battery to
the igniter only when the following conditions are met: i) said
cartridge is properly positioned within said chamber of said first
housing section. ii) said first and said second housing section are
completely and properly assembled, whereby said two terminals of
said electrical circuit contact said respective terminals of said
igniter. iii) said first switch is actuated by said object sensor
and thereby establishes an electrical connection, and iv) said
second switch is actuated by a user.
13. A device according to claim 8, wherein said assembly detecting
means exclusively comprise mechanical means.
14. A needleless hypodermic injection system for injecting a liquid
medication, which system comprises: a) an application device
according to claim 1 i) a housing having a length axis and an outer
contact surface which is adapted to be applied on a skin surface
through which an injection is to be applied; ii) said housing
containing ejection means causing ejection of said liquid
medication in order to perform an injection and actuator means for
activating said ejection means; and iii) position detecting means
for detecting whether said contact surface of said housing exerts a
predetermined pressure on said skin surface and whether at the same
time said length axis of said housing is positioned substantially
normal to said skin surface, the distribution of said pressure over
the area of said contact surface being substantially uniform, said
means for detecting enabling said actuator means when the latter
conditions are satisfied; and b) a disposable cartridge which
contains a medication and which comprises a propellant and an
igniter.
15. A medication cartridge for a needleless hypodermic injection
system according to claim 14 for injecting a liquid medication,
said cartridge comprising a housing adapted to contain: a) a first
chamber containing a medication unit configured and dimensioned to
store a volume of liquid to be injected, said medication unit
having a first region and a second region that are in liquid
communication with each other, said first region being deformable
and said second region having an injection outlet, b) a second
chamber containing a propellant, said first chamber being divided
by an elastic barrier in two zones, a first zone containing said
medication unit and a second zone which is in communication with
said second chamber, so that upon ignition of the propellant in the
second chamber gas generated thereby expands into said second zone
of said first chamber, exerts pressure on and deforms said barrier
which in turn transfers that pressure to and deforms said
deformable first region of said medication unit and thereby causes
ejection of said medication through said injection outlet, and c)
means for mechanically setting the volume available within said
cartridge for gas expansion, so that said volume has a selected
predetermined size.
16. A medication cartridge according to claim 15, further
comprising an envelope which surrounds said elastic barrier and
protects it from direct contact with hot gas generated by ignition
of said propellant in said second chamber.
17. A medication cartridge according to claim 16, wherein said
envelope also forms a gas seal between said housing and said
medication unit containing said liquid medication.
Description
PRIORITY TO RELATED APPLICATIONS
[0001] This application is a Continuation of Ser. No. 10/101,400,
filed Mar. 19, 2002 which is pending. This application claims the
benefit of U.S. Provisional Application Ser. No. 60/278,042, filed
Mar. 22, 2001.
FIELD OF THE INVENTION
[0002] The invention concerns a needleless hypodermic injection
system for injecting a liquid medication.
[0003] The invention also concerns a reusable application device
which is a first part of such a system.
[0004] The invention further concerns a disposable medication
cartridge which is a second part of such a system.
BACKGROUND OF THE INVENTION
[0005] Prior art systems and devices of the above mentioned kind
have important disadvantages. They have a complex structure and are
therefore not easy to assemble and to use, in particular for
patients which have some handicaps or are not in full possession of
their handling capabilities. Moreover they lack reliable means for
preventing accidental release of injections and their negative
consequences, e.g. loss of expensive medications and possible
injures inflicted to the user.
[0006] The main aim of the instant invention is therefore to
provide a system an application device, and a medication cartridge
of the above mentioned kind with which the above mentioned
drawbacks can be eliminated or at least substantially reduced.
SUMMARY OF THE INVENTION
[0007] According to a first aspect of the invention the above
mentioned aim is attained with a needleless hypodermic injection
system for injecting a liquid medication, which system
comprises:
[0008] (a) a disposable cartridge which contains a medication and
which includes a propellant and an igniter, and
[0009] (b) a reusable application device which comprises a pressure
chamber for receiving said cartridge, and actuation means including
an ignition system and means for ensuring reliability and safety of
the system.
[0010] According to a second aspect of the invention the above
mentioned aim is attained with a reusable application device for a
needleless hypodermic injection system for injecting a liquid
medication contained in a cartridge inserted into said application
device, said application device comprising
[0011] (a) a housing including a first section and a second section
which are adapted to be connected with each other to form a housing
assembly,
[0012] said first housing section comprising a chamber for
receiving a cartridge containing a medication unit which contains a
liquid medication,
[0013] said first housing section having a symmetry axis which
extends along its length and a front part having an outer contact
surface which is adapted to be applied on a skin surface, said
contact surface having an opening through which liquid medication
ejected from said cartridge can pass and be injected through said
skin surface,
[0014] (b) ejection means for causing ejection of said liquid
medication contained in said cartridge in order to perform an
injection, a first part of said ejection means being contained in
said cartridge and a second part of said ejection means being
contained in said second housing section,
[0015] c) assembly detecting means which reach a first
predetermined state when said first housing section is properly and
completely assembled with said second housing section to form said
housing assembly, said assembly detecting means being located
within said housing assembly,
[0016] d) position detecting means which are located in part within
said first housing section and in part in said second housing
section, said position detecting means reaching a second
predetermined state when the following conditions are
simultaneously satisfied by the relative position of said housing
assembly with respect to said skin surface,
[0017] d.2) said contact surface of said first section exerts a
predetermined pressure on said skin surface, the distribution of
said pressure over the area of said contact surface being
substantially uniform, and
[0018] d.3) said symmetry axis of said first section is positioned
substantially normal to said skin surface, and
[0019] e) actuator means for activating said ejection means, said
actuator means being normally disabled and becoming operable only
upon being enabled by a combination of predetermined effects
provided by
[0020] said assembly detecting means after they reach said first
predetermined state, and
[0021] said position detecting means when they reach said second
predetermined state.
[0022] According to a third aspect of the invention the above
mentioned aim is attained with a reusable application device for a
needleless hypodermic injection system for injecting a liquid
medication contained in a cartridge inserted into said application
device, said cartridge containing a propellant adapted to be
ignited by application of electrical energy to two electrical
contacts which are part of said cartridge, said application device
comprising
[0023] a) a housing including a first section and a second section,
each of these sections having a length axis and said first and
second housing sections being adapted to be connected with each
other to form a housing assembly, said housing assembly being so
configured and dimensioned that it is adapted to be held by a user
with one hand,
[0024] b) said first housing section comprising a chamber for
receiving a cartridge containing a liquid medication, said first
section having an outer contact surface which is adapted to be
applied on a skin surface through which an injection is to be
applied,
[0025] c) said second housing section containing electrical means
for causing ignition of a propellant contained in a cartridge
arranged in said chamber of said first housing section and actuator
means for activating said electrical means, and
[0026] d) position detecting means for detecting whether said
contact surface of said first section exerts a predetermined
pressure on said skin surface and whether at the same time said
length axis of said first section is positioned substantially
normal to said skin surface, the distribution of said pressure over
the area of said contact surface being substantially uniform, said
means for detecting enabling said actuator means when the latter
conditions are satisfied.
[0027] According to a fourth aspect of the invention the above
mentioned aim is attained with a reusable application device for a
needleless hypodermic injection system for injecting a liquid
medication, which application device comprises:
[0028] (a) a housing including a fist housing section and a second
housing section which are adapted to be assembled together by a
screwing operation,
[0029] said first housing section comprising a front part having an
injection outlet and a chamber adapted to receive a cartridge
containing a medication unit which contains the medication to be
injected, a propellant, and an igniter, and
[0030] (b) means for selectively activating said igniter of said
cartridge when predetermined conditions are fulfilled.
[0031] According to a fifth aspect of the invention the above
mentioned aim is attained with a medication cartridge for a
needleless hypodermic injection system for injecting a liquid
medication, said cartridge comprising a housing adapted to
contain:
[0032] (a) a first chamber containing a medication unit configured
and dimensioned to store a volume of liquid to be injected, said
medication unit having a first region and a second region that are
in liquid communication with each other, said first region being
deformable and said second region having an injection outlet,
and
[0033] (b) a second chamber containing a propellant,
[0034] said first chamber being divided by an elastic barrier in
two zones, a first zone containing said medication unit and a
second zone which is communication with said second chamber, so
that upon ignition of the propellant in the second chamber gas
generated thereby expands into said second zone of said first
chamber, exerts pressure on and deforms said barrier which in turn
transfers that pressure to and deforms said deformable first region
of said medication unit and thereby causes ejection of said
medication through said injection outlet, and
[0035] (c) means for mechanically setting the volume available
within said cartridge for gas said expansion, so that said volume
has a selected predetermined size.
[0036] The main advantages attained with the invention are as
follows:
[0037] Injections can only be performed when plurality of
predetermined necessary conditions for a correct injection are
satisfied. Therefore, the risk of accidentally released injections
and their negative consequences, e.g. loss of expensive medications
and possible injure of user, are substantially reduced.
[0038] A device and a system according to the invention are easy,
safe and comfortable to use, so that they can be assembled and used
by patients or other persons without any training or special
instructions.
[0039] The manufacturing cost of a device and a system according to
the invention is not higher than prior art devices for the same
purpose.
BRIEF DESCRIPTION OF THE DRAWINGS
[0040] The subject invention will now be described in terms of its
preferred embodiments with reference to the accompanying drawings.
These embodiments are set forth to aid the understanding of the
invention, but are not to be construed as limiting.
[0041] FIG. 1 shows a schematic cross sectional view of a basic
structure of a medication cartridge 11 used in a needleless
injection system according to the invention.
[0042] FIG. 2 shows a schematic cross sectional view of the basic
structure of an application device according to the invention
including a representation of a medication cartridge 11 according
to FIG. 1.
[0043] FIG. 3 shows a schematic cross sectional view of the
pressure chamber and locking means which are part of the
application device according to FIG. 2 and which are adapted to
enclose and contain a medication cartridge 11 of the type shown by
FIG. 1 during a high-pressure injection.
[0044] FIG. 4 shows a schematic cross sectional view of a complete
application device according to the invention without a medication
cartridge inserted thereinto.
[0045] FIG. 5 shows a side view of the nose section 42 of an
application device of the kind shown by FIG. 4.
[0046] FIG. 6 shows a first perspective view of the nose section 42
shown by FIG. 5.
[0047] FIG. 7 shows a second perspective view of the nose section
42 shown by FIG. 5.
[0048] FIG. 8 shows a first exploded view of components of the nose
section 42 shown by FIGS. 5-7.
[0049] FIG. 9 shows a second exploded view of components of the
nose section 42 shown by FIGS. 5-7.
[0050] FIG. 10 shows a first schematic representation of the
electrical ignition circuit of an application device of the kind
shown by FIG. 4.
[0051] FIG. 11 shows a second schematic representation of the
electrical ignition circuit of an application device of the kind
shown by FIG. 4.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
[0052] According to the invention a reusable application device is
used as part of a needleless hypodermic injection system for
injecting a liquid medication contained in a cartridge inserted
into said application device.
Medication Cartridge Assembly
[0053] As shown by FIG. 1 a medication cartridge assembly 11
according to the invention comprises components described
hereinafter.
[0054] A cartridge shell 12 made e.g. of a plastic material
contains among other components a sealed medication module which
comprises a nozzle body 13 and a flexible container wall 14 that
hermetically encloses a portion of the nozzle and forms a reservoir
15 for a liquid medication 16 stored in the sealed medication
module. This sealed module including liquid medication 16 stored
therein is manufactured under sterile conditions.
[0055] A part of the container wall 14 forms a break-off protective
cap 17 that covers a jet orifice 18 of nozzle body 13. Cap 17 is
removed by the user just prior to use.
[0056] An envelope 21 made e.g. of rubber surrounds the flexible
container wall 14 and serves as a protective barrier. Envelope 21
protects flexible wall 14 from direct hot gas contact, and prevents
hot gas from entering a fluid channel 22 within nozzle body 13 and
jet orifice 18 of nozzle body 13 even in the event of a break in
the flexible container wall 14. Envelope 21 also forms a gas seal
between the cartridge shell 12 and the medication module containing
the liquid medication 16.
[0057] Cartridge shell 12 unifies the components contained therein
and contains also gas generated within cartridge shell 12 by a gas
generator contained therein during actuation. The wall of cartridge
shell 12 may be relatively thin since it transfers the gas pressure
forces generated within cartridge shell 12 to a surrounding high
strength chamber that is part of a reusable actuation device
described hereinafter.
[0058] Injection energy is provided by a gas generator located in
the rear part of cartridge shell 12. This gas generator is a
subassembly consisting of a metal gas generator body 23 which has a
propellant containing chamber 24 located between an outlet orifice
plate 25 and a closure plug or closure plate 26. When the gas
generator is actuated in order to provide the energy necessary for
performing an injection of the liquid medication, a propellant
contained in propellant chamber 24 is ignited by an electrically
heated wire and produces hot gas that flows to gas pressure chamber
27 surrounding envelope 21, flexible container wall 14 and
medication reservoir 15 and an annular co-volume 28 the size of
which is defined by the axial position of a co-volume seal ring
34.
[0059] Heating wire adapted to be electrically heated is arranged
within propellant chamber 24. This heating wire is electrically
connected with ignition contacts 31, 32 arranged in closure plate.
When the medication cartridge assembly is properly positioned
within the reusable application device ignition contacts 31, 32
engage corresponding electrical contacts which are part of the
application device described hereinafter. Electric power is
deliverable to the heating wire 35 (shown in FIG. 11) arranged
within propellant chamber 24 through the latter contacts and
ignition contacts 31, 32 engaged therewith.
[0060] Cartridge shell 12 further contains an internal support 33
which e.g. a structure made of a plastic material that snaps into
cartridge shell 12 and holds the above described sealed medication
module and the gas generator in position. When cartridge assembly
11 is inserted into and properly positioned within an application
device described hereinafter in order to perform an injection, a
part of this application device pushes on the rear of cartridge
assembly 11 and clamps the closure plate 26 of the gas generator,
internal support 33, envelope 21 and the above described sealed
medication module into the nose of cartridge shell 12. Cartridge
assembly 11 remains so clamped during actuation thereof by the
application device for performing the injection. This clamping
action on cartridge assembly 11 assures that this assembly is
hermetically sealed to prevent hot gas leakage around jet orifice
18 of nozzle body 13.
[0061] When a cartridge assembly is actuated by the application
device, pressure exerted by gas surrounding a part of the sealed
medication module within cartridge shell 12 is transmitted to
liquid medication 16 contained in the sealed medication module
through flexible container wall 14. The pressure exerted in this
way on the liquid medication causes a collapsing of flexible
container wall 14 and this drives the liquid medication through jet
orifice 18 at high velocity. Peak pressure, up to 300 bar, occurs
at the beginning of the injection and forces a jet of liquid
medication to penetrate through a skin layer and thereby form a
fluid delivery channel into the subcutaneous tissue. The pressure
then drops to about 100 bar to complete the medication injection
through the so formed fluid delivery channel.
[0062] Ease of jet penetration varies between patients or between
injection sites on the same patient. The initial peak injection
pressure is therefore adjusted to control the jet penetration force
to an appropriate value. This adjustment is effected by positioning
co-volume seal ring 34 at a suitable axial position with respect to
cartridge shell 12 in order to set the value of the annular
co-volume 28.
[0063] Increasing co-volume 28 increases the expansion volume of
the gas generated and delivered by the gas generator and reduces
the initial peak pressure to a lower value. A co-volume setting
ring 48 that is part of the application device described
hereinafter slides into the rear of cartridge 11 during loading of
cartridge 11 into the application device, brings co-volume seal
ring 34 into a selected position and holds this ring in this
position.
[0064] A cartridge assembly 11 clamped into the actuation device
described hereinafter is a hermetically sealed assembly, and
retains as much as 100 bars pressure after actuation. The
application device must therefore release the clamping force in a
controlled way and allow that the gas pressure within cartridge 11
forces closure plug 26 of the gas generator out to break the seal
with the gas generator body 23 and vent the gas. This controlled
pressure release makes it easy to open the application device after
it is used to perform an injection and prevents that the amount of
pressure remaining in the cartridge after an injection may cause an
undesirable forceful opening of the application device that may
cause an injury to a user of the device.
Structure of an Application Device According to the Invention
[0065] The above described characteristics of cartridge assembly 11
define the basic functional requirements the application device has
to satisfy. Additional requirements ensure safe and easy operation
of the application device.
[0066] The force a user has to apply for loading a cartridge 11
into an application device and the force a user has to apply for
removing a cartridge 11 from the application device after use for
performing an injection must be low enough to allow easy and sure
operation of the application device by ill or elderly patients.
[0067] Actuation of the application device must not be possible
unless the device is fully closed and locked. Otherwise partial
engagement of the locking mechanism might lead to failure and
possible injury caused by the high pressure created during an
injection operation.
[0068] To ensure that actuation of the application device is not
possible unless the device is fully closed and locked, operation of
an application device according to the invention requires that the
nose part of the application device is pressed uniformly and with a
predetermined force against the skin surface to be injected before
actuation of the application device is enabled. Main objectives of
this security measure are to prevent accidental actuation resulting
in ejection of a liquid jet that might cause eye injury and also to
prevent wasted injections due to premature actuation of the
application device before the nose part thereof is properly pressed
against the skin surface at the injection site.
[0069] The outer surface of the application device should not have
any sharp edges or pinch points and the design of the application
device has to satisfy ergonomic requirements.
[0070] The shape of the application device has to be well adapted
to the function it has to perform and therefore the procedures for
loading and unloading a cartridge 11 into the application device
and for actuating the application device should be so obviously and
intuitively clear to the user that a minimum of user instruction is
necessary to ensure proper use of the application device.
[0071] Moreover, the application device and in particular the area
around the cartridge nozzle that contacts the skin during the
injection should be adapted to be easily cleaned.
[0072] The injection system formed by cartridge 11 and the
application device described hereinafter should be fail-safe and
resistant to tampering. Any faults in the device should result in
failure of device actuation rather than in an unexpected or
dangerous actuation. The design of the latter injection system
should be such that it discourages a "clever" person from modifying
or tricking the device so that it operates improperly.
[0073] The application device described hereinafter meets the
requirements outlined above.
[0074] As shown by FIG. 2, an application device 41 according to
the invention comprises two sections: a nose section 42 which
comprises a pressure chamber 49 defined by the interior of a shell
43 and adapted for receiving a cartridge assembly 11, and a base
section 44 which comprises among other components a breech block 45
and an electrical ignition system (not shown in FIG. 2).
[0075] Nose section 42 and a base section 44 are assembled in two
steps. In a first step a cartridge 11 is inserted into pressure
chamber 49 of nose section 42 and after that nose section 42 and
the cartridge 11 inserted thereinto are mechanically connected to
base section 44. For this purpose, nose section 42 and base section
44 are twisted with respect to each other 1/4 turn to provide
engagement of a set of locking lugs.
[0076] In a second step nose section 42 is twisted of about one
turn with respect to base section 44 for tightening a screw
mechanism that clamps cartridge assembly 11 with a required preload
of e.g. 200 Newton. At this point application device 41 is ready
for performing an injection. For this purpose, the user removes
break-off protective cap 17 from cartridge 11, presses jet orifice
18 of nozzle body 13 against a skin surface at the injection site,
and then presses an actuation switch to release an injection.
[0077] Interlocks prevent actuation of the application device if it
is not fully closed and if the skin contact surface of its nose
section 42 is not uniformly pressed against the skin surface.
[0078] A spent cartridge is removed by reversing the loading
process. For this purpose, nose section 42 is twisted of about one
turn with respect to base section 44 to release the clamp screw
mechanism and vent the residual cartridge gas pressure. The locking
lugs are then disengaged by a further 1/4 turn, and nose section 42
and base section 44 are separated from each other so that the spent
cartridge may be removed and discarded.
[0079] Application device 41 is a tightly integrated system that
comprises the following subsystems:
[0080] Pressure Chamber and Lock
[0081] Pressure chamber 49 and a lock which includes the above
mentioned breech block are a set of mechanical components that
enclose and contain a cartridge assembly 11 during a high-pressure
injection.
[0082] Housing
[0083] A housing encloses and supports the other subsystems which
form part of an application device according to the invention. This
housing also forms the surfaces the user grips to administer
injections and to open and close the application device for
loading, respectively unloading of a cartridge 11.
[0084] Electric Ignition System
[0085] An electric ignition system includes a battery, an actuation
switch, safety interlock switches and electrical connection leads.
The electrical ignition system supplies electric current to the
ignition contacts 31, 32 of cartridge 11 and thereby to ignition
wire 35 (see FIG. 11) to start an injection process when the user
presses the actuation switch.
[0086] Object Sensor
[0087] An object sensor comprises a mechanical structure
surrounding jet orifice 18 of nozzle body 13 of cartridge 11. This
mechanical structure comprises a skin contact surface of nose
section 42. Two diametrically opposite places of this skin contact
surface must be pressed against the injection site in order to
enable application device 41 to actuate a cartridge 11 which has
been loaded into application device 41.
[0088] The following sections describe each of the above mentioned
subsystems in detail.
[0089] Pressure Chamber and Lock Mechanism
[0090] FIG. 3 shows a general arrangement of a pressure chamber 49
and a lock mechanism 51. Pressure chamber 49 is the interior of a
generally cylindrical shell 43 with a reduced diameter opening 46
at one end and a full diameter opening 47 at the other end. The
shell 43 of pressure chamber 49 is manufactured from high strength
steel and dimensioned such that it will withstand about 900 bar
internal pressure (that is three times a 300 bar maximum working
pressure) without damage.
[0091] Lock mechanism 51 is part of a mechanical structure
contained in and carried by base section 44. In order to load a new
cartridge into the application device or to unload an spent
cartridge from the application device, nose section 42 and base
section 44 are disassembled as described above in order to separate
the shell 43 of pressure chamber 49 from lock mechanism 51.
[0092] When cartridge 11 is inserted into pressure chamber 49
break-off protective cap 17 and the outer end of nozzle body 13
extend through the reduced diameter opening 46 of the shell 43 of
pressure chamber 49. The shell 43 of pressure chamber 49 has a
clearance fit with respect to cartridge shell 12. During an
injection process the internal pressure within cartridge shell 12
expands it elastically and its outer wall contacts the internal
surface of the shell 43 of pressure chamber 49, thereby transfers
the pressure load to the shell 43 of pressure chamber 49 during the
injection process, and limits the mechanical stress on cartridge
shell 12. After an injection, the residual pressure in cartridge
shell is released by venting (as described above) and cartridge
shell elastically contracts. This restores the clearance fit of
cartridge shell 12 with respect to the shell 43 of pressure chamber
49 and this allows easy removal of a used cartridge. Nozzle body 13
of cartridge 11 has sufficient strength to bridge the reduced
diameter opening 46 and withstand the internal pressure in
cartridge 11 during an injection process.
[0093] Full diameter opening 47 of the shell 43 of pressure chamber
49 is closed when shell 43 is engaged with lock mechanism 51. Lock
mechanism 51 has several functions. A first function of lock
mechanism 51 is that it locks to the shell 43 of pressure chamber
49 and carries the axial pressure force (which is a function of the
cartridge internal diameter and the gas pressure) which tends to
separate lock mechanism 51 from the shell 43 of pressure chamber
49. A second function of lock mechanism 51 is that it carries the
ignition contacts of the application device that engage the
ignition contacts 31, 32 of cartridge 11. A third function of lock
mechanism 51 is that it carries an interchangeable co-volume
setting ring which serves for setting the axial position of the
co-volume seal ring 34 in cartridge 11. A fourth function of lock
mechanism 51 is that it comprises a clamp screw 52 that allows the
user to apply the necessary clamping force on cartridge 11 prior to
actuation thereof, and to release the residual pressure in
cartridge 11 in a slow and controlled way after an injection
process. A fifth function of lock mechanism 51 is that it contains
a mechanical interlock that assures that locking lugs are fully
engaged before clamp screw 52 can be turned to prepare and bring
the system composed by the application device and cartridge 11 to a
state that allows actuation of cartridge 11 by the application
device. Each of these functions is described in more detail in the
following sections.
[0094] A pair of male locking lugs 53 on the shell 43 of pressure
chamber 49 engage female pockets 54 in a receiver ring 55 of lock
mechanism 51 to form a structural connection. The user makes this
connection by inserting locking lugs 53 into receiver ring 55 with
an axial motion, and then rotating the shell 43 of pressure chamber
49 1/4 turn with respect to receiver ring 55 to engage locking lugs
53 with female pockets 54. This type of connection is widely used
in firearms and hose couplings because of its strength and
reliability.
[0095] After locking lugs 53 are fully engaged with female pockets
54, clamp screw 52 is turned to push breechblock 45 into cartridge
11. Clamp screw 52, the shell 43 of pressure chamber 49, receiver
ring 55 and breechblock 45 are all on a common axis, i.e. they are
coaxially arranged. This screw action preloads the sealing of
cartridge 11 with a force of about 200 Newtons, sets the axial
position of co-volume seal ring 34 to a selected position, and
pushes the ignition contacts of the application device against the
ignition contacts of cartridge 11 so that electrical contact is
established between these ignition contacts.
[0096] After an injection process is terminated, a 100 bar residual
pressure in cartridge 11 generates a force of about 1600 Newtons on
clamp screw 52. Under this mechanical load, the user turns clamp
screw 52 to retract breechblock 45 and vent cartridge 11. One of
the ends of clamp screw 52 has right hand threads that engage
matching threads in receiver ring 55, whereas the opposite end of
clamp screw 52 has left hand threads that engage matching threads
in breechblock 45. One or more pins in receiver ring 55 engage
matching axial slots in breechblock 45, and prevent rotation of
breechblock 45 while allowing axial motion thereof. The provision
of clamp screw 52 with the above mentioned different threads makes
it possible to obtain an axial displacement of breechblock 45 per
revolution of clamp screw 52 that is twice as long as the axial
displacement that would be obtained if clamp screw 52 had only a
single type of thread with the same thread pitch distance. A
suitable choice of thread diameter and pitch favorably influences
the amount of effort needed for disassembling, respectively
assembling application device 41. This is discussed in more detail
hereinafter.
[0097] A pair of interlock levers 56, 57 consisting each of a latch
portion 69 and an arm portion 68 are pivot mounted on a pivot 70 to
the receiver ring 55. Interlock levers 56, 57 lie in a plane that
includes the symmetry axis of receiver ring 55, and the pivot axes
are perpendicular to this plane and symmetrically placed on each
side of the symmetry axis of the receiver ring. Interlock levers
56, 57 are spring biased by a bias spring 60 so that the latch
portions 69 engage a pair of grooves (not shown) in clamp screw 52,
preventing screw rotation. When the shell 43 of pressure chamber 49
is inserted into receiver ring 55, the arm portions 68 of interlock
levers 56, 57 slip into a pair of cam grooves 58, 59 in the shell
43 of pressure chamber 49. Cam grooves 58, 59 are shaped to move
the arm portions 68 of interlock levers 56, 57 as the shell 43 of
pressure chamber 49 is rotated to engage locking lugs 53, so that
the latch portions 69 are removed from the clamp screw grooves. The
result is that rotation of clamp screw 52 is only possible when the
locking lugs 53 are fully engaged with pockets 54.
[0098] A second function of interlock levers 56, 57 is to prevent
rotation of lugs 53 and disengagement thereof from pockets 54 once
clamp screw 52 is rotated from the starting position to clamp
cartridge 11 and thereby the closure plug of cartridge 11 and
pressure chamber 49 by means of breechblock 45. When clamp screw 52
is rotated, the latch portions 69 of the interlock levers 56, 57
ride on the outside diameter of clamp screw 52, and can no longer
enter the clamp screw grooves and rotate about pivots 70. The arm
portions 68 of interlock levers 56, 57 are therefore immovable, and
bear against the sides of the cam grooves 58, 59 in the shell 43 of
pressure chamber 49 and block rotation of locking lugs 53. This
ensures that lugs 53 remain fully engaged with pockets 54 during
actuation of cartridge 11 and can only be disengaged after clamp
screw 52 is returned to the starting position. At this point the
latch portions 69 of interlock levers 56, 57 can again drop into
the clamp screw grooves, allowing the latches 69 of interlock
levers 56, 57 to rotate about the pivots 70.
[0099] A third function of interlock levers 56, 57 is to prevent
shell 43 of pressure chamber 49 from being inserted if clamp screw
52 is not in the starting position. In this condition the latch
portions 69 of the interlock levers 56, 57 ride on the outside
diameter of clamp screw 52, displacing the arm portions 68 of the
levers so that they do not enter the cam grooves in the shell 43 of
pressure chamber 49. This blocks the shell 43 of pressure chamber
49 from entering the receiver ring 55 far enough for the locking
lugs 53 to engage pockets 54. The situation in which the shell 43
of pressure chamber 49 is removed and the clamp screw 52 is not in
the starting condition is not normal, and indicates damage or
tampering. Correction of this anomalous state requires device
service or replacement.
[0100] By careful selection of the design parameters of clamp screw
52, the required effort to assembly and disassembly application
device 41 are approximately equal and this results in greatly
improved ease of use.
[0101] Frictional torque of clamp screw 52 varies in function of
axial load, screw thread diameter, and friction coefficient. Load
reaction torque varies in function of axial load and thread pitch.
The reaction torque adds to the friction torque in the closing
direction (when assembling application device 41), and increases
the user effort. Conversely, the reaction torque subtracts from the
friction torque in the opening direction (when disassembling
application device 41) and assists the user. Since the axial force
is about 200 Newtons in the closing direction and about 1600
Newtons in the opening direction, according to the invention the
parameters of clamp screw 52 are selected to equalize the opening
and closing torque. The following table summarizes the results of a
typical design calculation.
1 Parameter Value Clamp screw diameter 8 mm Screw thread friction
coefficient 0.12 Peak closing force 200 N Peak opening force 1600 N
Equalized opening and closing torque 20 N-cm Screw pitch (Total of
left and right 6 mm hand clamp screw sections)
[0102] Housing
[0103] FIG. 4 shows a cross section of application device 41
including the housing components. As well as containing the
functional components, the housing has important functions of its
own. The nose section 42 of the housing is rigidly connected to the
shell 43 of pressure chamber 49, and serves as one handle through
which the user applies opening and closing torque. The base section
44 of the housing is rigidly connected to clamp screw 52, and
serves as the other handle. The base section 44 of the housing
rotates relative to the receiver ring 55 and breechblock 45. In
combination, the nose section 42 and the base section 44 of the
housing also act as visual and tactile indicators, since they have
oval profiles that line up when the device is fully closed. Closure
of application device 41 is assisted by a spring-loaded pin and
detent 61 that latch the application device 41 in the closed
position. Additional functions and features of the housing will
become evident in the descriptions of other aspects of application
device 41.
[0104] FIGS. 5 to 9 show various views of the nose section 42 and
of some of its components. FIG. 5 shows a side view of the nose
section 42 of an application device of the kind shown by FIG. 4.
FIG. 6 shows a first perspective view of the nose section 42 shown
by FIG. 5. FIG. 7 shows a second perspective view of the nose
section 42 shown by FIG. 5. FIG. 8 shows a first exploded view of
components of the nose section 42 shown by FIGS. 5-7. FIG. 9 shows
a second exploded view of components of the nose section 42 shown
by FIGS. 5-7.
[0105] Electric Ignition System
[0106] FIGS. 10 and 11 show schematic representations of the
electric ignition system of application device 41.
[0107] In its simplest form, the electric ignition system of
application device 41 consists of a battery 62, an actuation switch
63 controlled by the user, electrical contacts that engage
electrical contacts of cartridge 11, and interconnection
conductors. The user loads a fresh cartridge 11 into application
device 41, closes and locks this device, removes break-off
protective cap 17, presses jet orifice 18 against the skin at the
injection site, and then presses push button 63 of the actuation
switch. Current passing through an electrically heated wire in the
gas generator of cartridge 11 lights the propellant and starts the
injection. The invention uses this basic approach, and adds
interlock mechanisms to reduce the chance of premature actuation
that could cause a hazard or waste an injection cartridge.
[0108] The physical configuration of the electric ignition system
of this invention is illustrated in FIG. 4. Except as noted, the
ignition components are attached to the base section 44 of the
housing. Battery 62 is permanently connected by soldering or a
similar means, and will normally last the life of application
device 41. The positive battery terminal 64 is electrically
connected to the input terminal of the normally open actuation
microswitch 71, and the negative terminal 65 is connected to the
input terminal of the normally open interlock microswitch 72. The
output terminal of the actuation microswitch 71 is connected to a
conductive spring member 73 that is biased into contact with the
central ignition contact pin 66. This contact connection is
required since the central ignition contact pin 66 rotates with the
receiver ring 55, not with the base section 44 of the housing. The
output terminal of the interlock microswitch 72 is connected to a
conductive spring member 67 that is biased into contact with the
sliding conductive transfer pin 74 in the receiver ring 55. The
transfer pin 74 forms a conductive path from the conductive spring
member 67 to the co-volume setting ring 48 and then to the
breechblock 45. Because the base section 44 of the housing and the
receiver ring 55 have rotational and axial relative motion, contact
takes place and ignition is possible only when clamp screw 52 is in
the predetermined actuation position.
[0109] The central ignition contact pin 66 presses against the
cartridge center ignition contact 32. The pin head 75 is
structurally connected to the sliding breechblock 45, but
electrically isolated by an insulating bushing 76. The pin shaft
passes through clearance holes in the breechblock 45 and clamp
screw 52, and is supported on center by an insulating sleeve
bearing 77 to maintain electrical isolation.
[0110] The electrically conductive sliding breechblock 45 presses
against the outer ignition contact 31 of cartridge 11. As described
above, current can only flow to the breechblock 45 when the clamp
screw 52 is in the actuation position and the transfer pin 74 makes
contact with the conductive spring member 67.
[0111] When the interlock microswitch 72 is closed and the clamp
screw 52 is in the actuation position, the actuation microswitch 71
is the only remaining barrier to current flow through the ignition
contacts and the electrically heated wire 35 in cartridge 11. This
results in the battery voltage appearing between the input and
outlet terminals of the actuation microswitch 71. This "ready to
actuate" condition is visually indicated by a LED 78 connected
across the terminals. Actuation then takes place when the user
closes the actuation microswitch 71 by pressing push button 63.
[0112] A mechanism consisting of a pushbutton 63, coil spring 81,
pin lever 82 and flat spring 83 is used to close the actuation
microswitch 71 when the user presses the push button 63. This
arrangement allows the pushbutton 63 to be positioned so that it is
convenient for the user, while the actuation microswitch 71 is
positioned where housing space is available. The pushbutton 63
slides in a sleeve 84 in the housing, and is biased out by the coil
spring 81. The pin lever 82 serves a dual purpose. First, it is
pressed into the pushbutton 63 and extends into openings in the
sides of the sleeve 84 to retain the pushbutton 63 in the housing.
Second, it acts as a lever that transfers the pushbutton motion to
the flat spring 83 that engages the actuation microswitch operating
plunger 85. The pin lever 82 pivots in a hole in the side of the
sleeve 84 nearest the nose section 42 of the housing of the
application device 41, and swings through a slot 86 in the opposite
side. The flat spring 83 is anchored at one end, and passes over
the microswitch 71 and extends to engage the end of the pin lever
82. When the pin lever 82 swings, it deflects the flat spring 83
towards the actuation microswitch 71 and pushes the actuation
plunger 85. The sleeve 84 in the housing is made of translucent
plastic that is illuminated by the "ready to actuate" LED 78.
[0113] The schematic representation of the electrical ignition
system shown by FIG. 10 illustrates the fact that in order that an
injection can be performed with application device 41 the following
switches have to be closed: switches 71, 72, and switch formed by
lock mechanism 51, spring-loaded pin and detent 61 and electrical
conductive transfer pin 74. This latter switch is only then closed
when the application device 41 is completely assembled, that is
when the components contained in nose section 42, in base section
44, and the cartridge 11 are all in the proper position with
respect to each other.
[0114] The schematic representation of the electrical ignition
system shown by FIG. 11 illustrates the state of this system when
the application device 41 is completely assembled and all necessary
contacts for the ignition are established with exception of
switches 71 and 72 which are still open. In this state LED 78
received a current limited by resistor 79. This current is well
below the value necessary to cause ignition by electrically heating
ignition wire 35, but is large enough to cause light emission by
LED 78 and thereby signalize that application device 41 would
become ready for performing an injection if and when properly
positioned on the injection site.
[0115] When the application device 41 reaches a proper position on
the injection site, switch 72 is closed by this positioning, and
actuation of push button 63 by the user can then cause closure of
switch 71. If this happens, the electrical ignition circuit is
closed and a sufficiently large current is fed to ignition wire 35
to cause ignition of the propellant in cartridge 11.
[0116] Object Sensor/Position Detector
[0117] The object sensor or position detector requires the nose
section 42 of the housing of the application device 41 to be
pressed uniformly against the skin surface at the injection site
before actuation is possible/allowed. The object sensor/position
detector is illustrated in FIG. 4. The nose section 42 of the
housing includes a flat annular surface 91 which surrounds the end
of the shell 43 of pressure chamber 49 that protrudes from the
housing and the injection nozzle. A pair of diametrically opposed
sensor pins 92, 93 slide in holes in the housing, and their ends
extend a short distance above the surface in the rest position. The
interlock system according to the invention requires that both
sensor pins 92, 93 are pushed flush with the annular surface 91 to
enable execution of an injection. Sensor pins 92, 93 support a
concentric rigid metal sensor ring 94 that is free to pivot at the
contact points with the sensor pins 92, 93. This defines the
condition that two or more separate points must be pressed to push
the sensor ring 94 and both pins 92, 93 flush with the annular
surface 91 and enable execution of an injection. If the sensor ring
94 is pressed at any one point around its circumference it will
tip, and at most one of the two sensor pins 92, 93 will be pushed
flush with the annular surface 91. The annular area, including the
sensor ring 94 and sensor pins 92, 93, is covered by a flexible
rubber boot 95. The inner edge of the boot 95 is bonded to the
shell 43 of the pressure chamber 49 at a bond point 105, and the
outer edge of boot 95 fits in a groove in the nose section 42 of
the housing. The boot 95 forms a smooth, easily cleaned surface and
protects the mechanism. It also retains the sensor ring 94 and
holds it in the proper spatial relationship with the sensor pins
92, 93 at the rest position.
[0118] The sensor pins 92, 93 push a relay ring 96 inside the nose
section 42 of the housing. The relay ring 96 in turn pushes a tilt
plate 97. The tilt plate 97 contacts the relay ring 96 with two
diametrically opposed raised pivot points 98 (98a respectively
98b), and two diametrically opposed legs 99 (99a respectively 99b)
extend towards the base section 44 of the housing. The legs 99 are
offset 90 degrees from the pivot points 98, and lie in the same
plane as the sensor pins 92, 93. A return spring 101 formed from
sheet spring material pushes the tilt plate 97, relay ring 96 and
sensor pins 92, 93 towards the nose section 42 of the housing so
that the sensor ring 94 is pushed out to the rest position. A cover
plate 102 on the surface of the nose section 42 of the housing that
abuts the base section 44 of the housing supports the return spring
101 and shields the mechanism. The tilt plate legs 99 pass through
holes in the cover plate 102, with their ends flush with the outer
surface in the rest position.
[0119] When the nose section 42 of the housing is attached to the
base section 44 of the housing and the clamp screw 52 is locked,
one of the two tilt plate legs 99 is aligned with the interlock
push pin 103. This pin contacts the interlock microswitch plunger
104, and closes the interlock microswitch 72 when it is pushed by
one of the tilt plate legs 99. The other tilt plate leg contacts
the base section 44 of the housing and forms a pivot point. If the
sensor ring 94 pushes both sensor pins fully, then the relay ring
96 is pushed uniformly against the two tilt plate pivot points.
This causes the tilt plate 97 to rotate around the pivot point
formed by the leg in contact with the housing so that the other leg
extends, pushes the interlock push pin 103, and closes the
interlock microswitch 72. In the event that only one sensor pin 92
or 93 is pushed, the relay ring 96 tilts rather than moving
uniformly. The two points on the relay ring 96 that contact the
tilt plate 97 pivots move only half the full distance, with the
result that the tilt plate leg 99 moves only half the full distance
and does not close the interlock switch 72.
[0120] This above described object sensor/position detector has a
number of useful features. First, it is electromechanical, and does
not contain any electronic devices that are sensitive to and whose
operation can be affected by spurious signals from electrostatic
discharge or other sources of electromagnetic interference. Second,
the electric ignition circuit is totally within the base section 44
of the housing, with no connections to the removable nose section
42 of the housing that could compromise reliability. Third,
additional safety is provided by the fact that the device must be
fully closed and locked to align the tilt plate leg 99 with the
interlock push pin 103. Fourth, the structure of the object
sensor/position detector is symmetrical, so that the nose section
42 of the housing may be connected to the base section 44 of the
housing in either of two positions which are angularly spaced from
each other of 180 degrees.
[0121] List of Reference Numbers
[0122] 11 medication cartridge/cartridge assembly
[0123] 12 cartridge shell
[0124] 13 nozzle body
[0125] 14 flexible container wall
[0126] 15 medication reservoir
[0127] 16 liquid medication
[0128] 17 break-off protective cap
[0129] 18 jet orifice
[0130] 19
[0131] 20
[0132] 21 envelope
[0133] 22 fluid channel
[0134] 23 gas generator body
[0135] 24 propellant chamber
[0136] 25 outlet orifice plate
[0137] 26 closure plug/closure plate
[0138] 27 gas pressure chamber
[0139] 28 annular co-volume
[0140] 29
[0141] 30
[0142] 31 ignition contact
[0143] 32 ignition contact
[0144] 33 internal support
[0145] 34 co-volume seal ring
[0146] 35 electrically heated wire/ignition wire
[0147] 36
[0148] 37
[0149] 38
[0150] 39
[0151] 40
[0152] 41 application device
[0153] 42 nose section
[0154] 43 shell of pressure chamber
[0155] 44 base section
[0156] 45 breech block
[0157] 46 reduced diameter opening
[0158] 47 full diameter opening
[0159] 48 co-volume setting ring
[0160] 40 pressure chamber
[0161] 50
[0162] 51 lock mechanism
[0163] 52 clamp screw
[0164] 53 male locking lugs
[0165] 54 female pockets
[0166] 55 receiver ring
[0167] 56 interlock lever
[0168] 57 interlock lever
[0169] 58 cam groove
[0170] 59 cam groove
[0171] 60 bias spring
[0172] 61 spring-loaded pin and detent
[0173] 62 battery
[0174] 63 push button/actuation button
[0175] 64 positive terminal
[0176] 65 negative terminal
[0177] 66 central ignition contact pin
[0178] 67 conductive spring member
[0179] 68 arm portion
[0180] 69 latch portion
[0181] 70 pivot
[0182] 71 actuation micro-switch
[0183] 72 interlock micro-switch
[0184] 73 electrical conductive spring member
[0185] 74 electrical conductive transfer pin
[0186] 75 pin head
[0187] 76 insulating bushing
[0188] 77 insulating sleeve bearing
[0189] 78 Light Emitting Diode (LED)
[0190] 79 electrical resistance
[0191] 80
[0192] 81 coil spring
[0193] 82 pin lever
[0194] 83 flat spring
[0195] 84 sleeve
[0196] 85 operating plunger/actuation plunger
[0197] 86 slot
[0198] 87
[0199] 88
[0200] 89
[0201] 90
[0202] 91 flat annular surface
[0203] 92 sensor pin
[0204] 93 sensor pin
[0205] 94 metal sensor ring
[0206] 95 flexible rubber boot
[0207] 96 relay ring
[0208] 97 tilt plate
[0209] 98 pivot point (98a, 98b)
[0210] 99 leg (99a, 99b)
[0211] 100
[0212] 101 return spring
[0213] 102 cover plate
[0214] 103 interlock push pin
[0215] 104 interlock microswitch plunger
[0216] 105 bond point
[0217] Although a preferred embodiment of the invention has been
described using specific terms, such description is for
illustrative purposes only, and it is to be understood that changes
and variations may be made without departing from the spirit or
scope of the following claims.
* * * * *