Patent Description:
In the field of combat simulation devices, it is known to deliver an electrical shock to a user through a pair of electrodes in close proximity to the skin of a user to simulate a combat injury. <CIT> discloses an example of a device for controlling the characteristics of an electrical impulse to be delivered to a user through a pair of electrodes during stress exposure training. It is preferred that the electrodes be mounted directly against the skin of the user to ensure the electrical impulse is received by the user in the manner intended to effectively simulate a stress exposure environment. When using the device with multiple users, various adjustable mounting hardware may be required to accommodate users of different size and shape, and then the mounting hardware requires time consuming sanitation between use by different users.

Electrodes for forming direct contact with a user are known in the field of acquiring a biological signal emitted from a living body. In the instance of acquiring a biological signal, electrodes for forming an electrical contact with a user are known to be incorporated into garments, however, when relying on garments to support electrodes in contact with a user, a large variety of different sizes and shapes of garments are required to accommodate different users. United States Patent Application Publication No. <CIT>, discloses a biomedical electrode which is detachably attached to a garment and includes an electrode coming into contact with a living body clothed in the garment to acquire a biological signal emitted by the living body. The electrode connects through the garment using a post connector protruding from the electrode portion that contacts the user, in which the post connector has an enlarged head required to form a firm connection with a female connector at the exterior side of the garment. The shape of the enlarged head of the post connector requires a destructive slot to be formed in the garment to communicate through the fabric of the garment. Furthermore, the individual electrode can only be used for acquiring a biological signal emitted by the living body and is incapable of being used to deliver an electrical shock to a user due to the single contact of the electrode with the user.

The Japanese patent application No. <CIT> discloses a bioelectric signal measuring apparatus capable of accurately measuring bioelectric signals over a long period of time.

According to one aspect of the invention there is provided an electrode assembly for attachment to a garment worn by a user as specified in claim <NUM>.

The use of a pin connector which is self-penetrating through a fabric material in a non-destructive manner, allows the electrode to be mounted on a large variety of garments provided by the user without damaging the garment so that the garment can continue to be used as clothing after removal of the electrode.

In some embodiments, the use of two electrodes that communicate with a common housing allows electronics within the housing to be configured to deliver an electrical shock to the user in an effective manner, while maintaining the housing and most of the mounting hardware externally of the garment in a sanitary manner.

Preferably the pin connector includes a recess formed therein defining a catch arranged to be engaged by the socket connector. The recess may comprise an annular groove extending about a circumference of the pin connector.

The pin connector and the socket connector are preferably formed of conductive material defining a conductive path arranged to communicate the electrical signal between said at least one electrode and the electronic component on the housing in the mounted position.

The electrode may be conical in shape so as to be tapered outwardly from the pad towards an apex. Preferably the apex has an interior angle that is greater than <NUM> degrees.

Preferably a pair of electrodes are provided, in which each electrode has a respective first connector associated therewith which connects the electrode to the electronic component of the housing. The pad may be a single body commonly supporting both electrodes therein.

The pad preferably has an outer surface for engaging the user that is formed of a resilient, non-conductive, and electrically insulating material, for example a rubber-like material. The outer surface may also be textured for gripping the user.

The assembly preferably includes a battery supported on the housing so as to be arranged to deliver an electrical signal from the housing to the user through said at least one electrode.

When (i) the housing has an inner surface for abutment against the fabric layer bound by a prescribed perimeter shape of the housing and (ii) the pad has an inner surface for abutment against the fabric layer bound by a prescribed perimeter shape of the pad, preferably (iii) the prescribed perimeter shape of the housing and the prescribed perimeter shape of the pad being substantially identical to one another.

The housing may have an outer surface opposite the second connector on the housing that has a smooth convex shape so as to minimize the housing being caught on external objects.

The electronic component of the housing may include (i) a controller having a processor and a memory storing programming instructions arranged to be executed by the processor, and (ii) a transceiver connected to the controller so as to be arranged to communicate signals wirelessly between the controller and an external electronic device.

Alternatively, the electrical component of the housing may be arranged to (i) receive a biological signal that is (a) emitted by a body of the user and (b) acquired by said at least one electrode, and (ii) transmit the biological signal to an external electronic device.

In the illustrated embodiment, the electronic component of the housing includes an electrical shock generator supported on the housing in communication with the electrodes so as to be arranged to deliver an electrical impulse to the user through the electrodes that causes non-injurious pain to the user. Preferably said at least one pad comprises a single body commonly supporting both electrodes therein.

One embodiment of the invention will now be described in conjunction with the accompanying drawings in which:.

In the drawings like characters of reference indicate corresponding parts in the different figures.

Referring to the accompanying figures there is illustrated a garment supported electrode assembly generally indicated by reference numeral <NUM>. The electrode assembly <NUM> is particularly suited for supporting one or more electrodes <NUM> relative to a garment <NUM> to be worn by a user <NUM>.

The garment may be any type or shape to be worn about a portion of the body of the user, for example a shirt worn about the torso or pants worn about the legs of the user. The garment has a fabric layer <NUM>, for example a woven knit type material, in which the garment is worn such that an inner surface of the fabric layer faces inwardly to lie against the skin of the user and an opposing outer surface of the fabric layer is located at an external side of the garment.

In some instances, the electrodes may be used in a medical environment to acquire a biological electrical signal emitted by the body of the user. In this instance, the electrodes acquire the signal from the body of the user such that the electrode assembly can further transmit the signal to an external electrical device used to interpret the signal.

In the illustrated embodiment, the electrodes <NUM> are used together with a stress exposure training system to simulate a stress exposure environment, for example a combat simulation system. In this instance, a target device, for example a vest <NUM> having signal receivers <NUM> thereon is worn by the user. A simulated weapon <NUM> may arranged to generate a coded pulsed beam of light to simulate a projectile. A controller <NUM> on the target device determines that the user has been hit with a simulated projectile during a training exercise when the signal receiver <NUM> receive the coded pulsed beam of light emitted by the simulated weapon <NUM>. The controller <NUM> then generates a wireless activation signal that can be detected and received by the electrode assembly <NUM> to deliver a non-injurious, but painful electrical shock to the skin of the user as described in further detail below.

In some instances, multiple assemblies <NUM> may be worn on different parts of the garment <NUM> in which the different assemblies <NUM> each communicate wirelessly with a common main controller <NUM> as shown schematically in <FIG>. Preferably, each assembly <NUM> responds to a unique wireless activation signal from the controller <NUM> so as to activate different assemblies <NUM> to deliver electrical shocks to different parts of the body based on different activation criteria stored on the controller <NUM>.

In further embodiments, the controller <NUM> that generates the wireless activation signal for one or more assemblies <NUM> may be any type of electronic device capable of wireless communication with the assemblies <NUM>, for example other simulated training equipment that can be triggered within a simulated environment for training, or a smartphone or tablet computer operated by an instructor monitoring the simulated environment for training.

The electrode assembly <NUM> generally includes a housing <NUM> arranged to be supported externally on the garment <NUM> and a pad <NUM> arranged to be supported internally on the garment. The housing <NUM> and the pad <NUM> are arranged to be connected to one another with the fabric layer <NUM> of the garment therebetween in a mounted position of the assembly, while remaining readily releasable from one another to remove the electrode assembly from the garment when no longer in use.

The housing <NUM> and the pad <NUM> are both elongate in a lateral direction between opposing ends <NUM> of the assembly. The housing <NUM> includes (i) an inner surface <NUM> facing inwardly to engage the outer surface of the fabric layer in the mounted position and (ii) an opposing outer surface <NUM> opposite the inner surface <NUM> and that faces outwardly away from the garment. The pad <NUM> similarly includes (i) an inner surface <NUM> facing towards the fabric layer to engage the inner surface of the fabric layer in the mounted position and (ii) an opposing outer surface <NUM> opposite the inner surface <NUM> so as to be arranged to be engaged against the skin of the user in the mounted position.

The pad <NUM> of the assembly <NUM> comprises a flat sheet having a minimal thickness between the inner surface <NUM> and the outer surface <NUM> as compared to the length of the faces in the lateral direction and the perpendicular width of the faces between the top and bottom edges thereof. The pad may be moulded of an electrically insulating material that is non-conductive and resilient for example rubber, a plastic or other resilient materials.

Alternatively, the pad <NUM> may comprise a rigid body. In this instance, the outer surface may be defined by a liner of resilient material for engagement with the skin of the user. The outer surface may be textured with ridges or grooves formed therein for better gripping relative to the skin of the user.

In the illustrated embodiment, two electrodes <NUM> are commonly mounted on the single body of the pad <NUM> at spaced apart positions in the lateral direction. In further embodiments, a single electrode <NUM> may be mounted on a single body of the pad <NUM> which in turn is coupled to a single housing <NUM>, for example in applications where a biological signal emitted from the body of the user is acquired by the electrode. In yet further embodiments, the pad <NUM> may comprise two separate bodies each supporting a respective electrode therein in which the two bodies are commonly mounted on a single housing <NUM>, for example to deliver an electrical shock through the two electrodes.

Each electrode <NUM> is mounted in a protruding relationship relative to the outer surface <NUM> of the pad that engages the user. The exterior head of the electrode may be cone shaped so as to be tapered outwardly and away from the surface of the pad towards a central apex of the electrode. Preferably the apex has an interior angle which is greater than <NUM>° such that the apex is not too sharp in a manner that would cause discomfort to the user but remains pointed to form a firm contact of the tip of the electrode with the skin of the user.

Each electrode includes a first connector <NUM> associated therewith. In the illustrated embodiment the first connector <NUM> is a pin connector comprising a post connected to the exterior head of the electrode <NUM> to extend through a corresponding mounting aperture in the pad for protruding inwardly beyond the opposing inner surface <NUM> of the pad. The post forming the first connector <NUM> is round in cross-sectional shape and has an outer diameter which is much smaller than the diameter of the exterior head of the electrode <NUM>.

The diameter of the post forming the first connector <NUM> is quite small and is tapered at the free end thereof to form a pointed tip <NUM> such that the first connector <NUM> can be readily self-penetrated through the fabric layer. When the fabric layer comprises a woven knit material with a tight weave having no visible gaps therein, the diameter of the first connector is such that the pointed tip is able to spread individual strands of the woven knit to allow passage of the first connector through the fabric in a non-destructive manner.

A retainer catch <NUM> is formed at an intermediate location along the post of the first connector at a location spaced from the inner surface <NUM> of the pad. The catch <NUM> is formed as a recessed groove extending about the full circumference of the post to assist in retaining the pad <NUM> in a mounted position relative to the housing as described in further detail below.

The exterior head of the electrode <NUM> and the post of the first connector <NUM> are formed as a continuous unitary body of conductive metal so that electrical signals can be communicated through the first connector <NUM> to the electrode and from the electrode through the first connector <NUM>.

The housing <NUM> has an outer perimeter shape which is substantially identical to the outer perimeter shape of the pad <NUM>. The inner side <NUM> that mounts against the fabric layer fully spans the length and width of the housing so as to be bound by the perimeter shape of the housing, similarly to the inner surface <NUM> that spans the complete interior side of the pad <NUM> so as to be bound by the perimeter shape of the pad. The inner surface <NUM> is flat and rigid.

A perimeter wall <NUM> defining the perimeter shape of the housing protrudes perpendicularly outwardly about the full perimeter of the inner surface <NUM>. The outer surface <NUM> is smooth and rounded in profile and extends continuously from the perimeter wall such that the perimeter wall and the outer face <NUM> collectively form a smooth, domed structure which is generally convex in shape and which is devoid of any sharp edges or corners.

The housing has a hollow interior supporting various electrical components therein. This includes a printed circuit board <NUM> having a processor and a memory including programming instructions thereon which are arranged to be executed by the processor for performing the various functions of the assembly. The printed circuit board incorporates a wireless transceiver <NUM> therein which is arranged to transmit and receive wireless electronic signals for communicating information between the controller and an external electronic device such as the controller <NUM> of the training system shown in <FIG>, to receive an activation signal and to activate delivery of an electrical shock to the user for example.

A battery <NUM> is also supported within the housing to provide electrical power to the printed circuit board <NUM>. A wireless charging coil may be incorporated into the power supply circuit such that the battery is arranged to be charged by induction simply by placing the housing <NUM> in proximity to an induction charging unit.

An electrical impulse device <NUM> is also supported within the interior of the housing in communication with the controller <NUM> to receive electrical power from the battery <NUM>. The electrical impulse device is also in communication with both of the electrodes in the mounted position as described in further detail below. When an activation signal with prescribed shock settings is received by the controller <NUM>, the controller activates the electrical impulse device which in turn generates a high-voltage electrical signal for delivery to the electrodes to deliver a painful, yet non-injurious electrical shock to the user.

Electrical communication of the electrodes <NUM> with the electrical impulse device, as well as structural mounting of the pad <NUM> relative to the housing is accomplished by a pair of second connectors <NUM>. Each second connector <NUM> is supported on the housing at the inner side thereof in alignment with a respective one of the first connectors <NUM>. The second connectors <NUM> are thus laterally spaced apart from one another by a similar spacing as the first connectors <NUM>. The second connectors <NUM> are also positioned relative to the perimeter shape of the housing in a similar manner as the first connectors <NUM> relative to the perimeter shape of the pad such that alignment of the perimeter shapes of the housing and pad in the mounted position is sufficient to align each first connector <NUM> with the corresponding second connector <NUM>.

Each second connector <NUM> is a socket connector which is arranged to receive a respective one of the pin connectors of the first connector therein in the mounted position. The socket is formed of a conductive material and is tubular in shape, having an interior diameter which is very similar to the outer diameter of the post of the respective first connector <NUM>. The post of the first connector <NUM> may be sized for a slight interference fit relative to the socket of the corresponding second connector <NUM> to ensure that the first connector is frictionally retained within the second connector in the mounted position while remaining releasable if the friction forces are overcome by a user pulling the pad and housing apart from one another.

A locking protrusion <NUM> is supported within each socket connector <NUM> to protrude inwardly beyond the inner diameter thereof for alignment with the catch <NUM> on the corresponding first connector <NUM>. The protrusion <NUM> is preferably resiliently supported relative to the socket such that the protrusion can be flexed outwardly in non-interference with the interior diameter of the second connector <NUM> as the first connector is inserted therein; however, the protrusion <NUM> is biased into the interior space of the socket for insertion into the recessed groove of the catch <NUM> once the pad and housing are in the mounted position relative to one another. In this manner, the first connector <NUM> forms a snap-fit connection into the corresponding second connector.

The conductive material forming the tubular socket of each second connector is electrically and conductively connected to the electrical impulse device and the printed circuit board such that the electrical signal representing the impulse shock to be delivered to the user can be transmitted directly from the components within the housing to the electrodes <NUM> in contact with the skin of the user in the mounted position of the assembly.

The electrode assembly <NUM> as described herein can be used with a variety of different garments and the pin connectors <NUM> which are penetrated through the fabric material of the garment have a small diameter and a pointed tip for ease of penetration between the knit fibers of the fabric even when no visible holes are provided in the fabric, without causing any damage to the fabric.

The pad <NUM> is intended to be supported at the inner surface of the fabric layer while the housing is mounted at the outer surface. Once the first connectors <NUM> are penetrated through the fabric layer and inserted into the corresponding second connectors of the housing, the housing is ready for pairing with an additional electronic device, for example (i) a controller <NUM> of the combat simulation system described above, or (ii) in the instance of medical electrodes, other external medical equipment capable of interpreting biologically emitted electrical signals captured by the electrodes. In the illustrated embodiment, when a pulsed signal hits the sensor of the target device such that the controller <NUM> generates an activation signal transmitted wirelessly to the controller <NUM> of the electrode assembly, the controller <NUM> of the electrode assembly <NUM> activates the electrical impulse device to generate an electrical signal delivered to the electrodes which causes an electrical shock to be delivered to the user.

When use is no longer required, the electrode assembly can be removed from the garment by overcoming the retention forces of the first connectors <NUM> received within the second connectors <NUM> and the retention force of the resiliently supported locking protrusions <NUM> to separate the pad and housing from one another for subsequent removal from the fabric material. When using the assembly with the new user, the pad <NUM> supporting the electrodes <NUM> thereon which contacts the user can be simply replaced and the housing containing the various electrical components noted above can be reused with a different pad <NUM> interchanged thereon while similarly supporting the assembly on a new garments associated with the new user. The simplicity of interchanging the pad <NUM> minimizes the amount of sanitation required between different uses on different users as the externally supported housing requires thorough cleaning between uses.

Claim 1:
An electrode assembly (<NUM>) for attachment to a garment (<NUM>) worn by a user (<NUM>), the garment (<NUM>) having a fabric layer with an inner surface supported against the user (<NUM>) and an outer surface opposite the inner surface at an exterior of the garment (<NUM>), the electrode assembly (<NUM>) comprising:
at least one electrode (<NUM>) arranged to directly contact the user (<NUM>);
a first connector (<NUM>) associated with said at least one electrode (<NUM>);
a housing (<NUM>) arranged to be supported externally against the outer surface of the fabric layer, the housing (<NUM>) including an electronic component therein;
a second connector (<NUM>) supported on the housing (<NUM>) in association with the first connector (<NUM>);
one of the first connector (<NUM>) and the second connector (<NUM>) comprising a pin connector and another one of the first connector (<NUM>) and the second connector (<NUM>) comprising a socket connector; and
said at least one electrode (<NUM>) and the electronic component being in electrical communication with one another in the mounted position so as to be arranged to communicate an electrical signal between said at least one electrode (<NUM>) and the electronic component on the housing (<NUM>) in the mounted position;
characterized by:
a pad (<NUM>) supports said at least one electrode (<NUM>) thereon wherein the pad (<NUM>) is arranged for mounting against the inner surface of the fabric layer;
the first connector (<NUM>) is supported on the pad (<NUM>);
the socket connector is arranged to receive the pin connector therein to releasably attach the housing (<NUM>) to the pad (<NUM>) in a mounted position of the assembly;
the pin connector is shaped to be self-penetrating through the fabric layer in a non-destructive manner so as to be arranged for insertion through the fabric layer between the pad (<NUM>) at the inner surface and the housing (<NUM>) at the outer surface in the mounted position; and
the electronic component of the housing (<NUM>) includes an electrical impulse device supported on the housing (<NUM>) in communication with said at least one electrode (<NUM>) so as to be arranged to deliver an electrical impulse to the user (<NUM>) through said at least one electrode (<NUM>) that causes non-injurious pain to the user (<NUM>).