阅读说明：本技术 筒监控系统 (Cartridge monitoring system ) 是由 C·L·莱切克 于 2019-06-07 设计创作，主要内容包括：一种火灾抑制系统包括：罐,所述罐被配置用于容纳火灾抑制剂；筒,所述筒被配置用于容纳加压驱动气体,所述筒包括导电区段；致动器,所述致动器联接到所述罐并选择性地联接到所述筒；以及筒监控系统,所述筒监控系统联接到所述致动器。所述致动器被配置用于选择性地将来自所述筒的所述加压驱动气体供应至所述罐,从而将所述火灾抑制剂从所述罐中喷洒出。所述筒监控系统包括：(a)第一接触件和第二接触件,所述第一接触件和所述第二接触件被配置用于当所述筒联接到所述致动器时与所述筒的所述导电区段接合；以及(b)电解释器,所述电解释器联接到所述第一接触件和所述第二接触件并且被配置用于确定所述筒的所述导电区段是否正与所述第一接触件和所述第二接触件接合以形成闭合电路。(A fire suppression system comprising: a tank configured to hold a fire suppressant; a cartridge configured to contain a pressurized drive gas, the cartridge comprising an electrically conductive section; an actuator coupled to the canister and selectively coupled to the cartridge; and a cartridge monitoring system coupled to the actuator. The actuator is configured to selectively supply the pressurized drive gas from the cartridge to the canister to thereby fire suppressant the fire suppressant from the canister. The cartridge monitoring system comprises: (a) a first contact and a second contact configured to engage with the conductive section of the barrel when the barrel is coupled to the actuator; and (b) an electrical interpreter coupled to the first and second contacts and configured to determine whether the conductive section of the barrel is engaging the first and second contacts to form a closed circuit.)

1. A fire suppression system, comprising:

a tank configured to hold a fire suppressant;

a cartridge configured to contain a pressurized drive gas, the cartridge comprising an electrically conductive section;

an actuator coupled to the canister and selectively coupled to the cartridge, wherein the actuator is configured to selectively supply the pressurized drive gas from the cartridge to the canister to thereby spray the fire suppressant from the canister; and

a cartridge monitoring system coupled to the actuator, the cartridge monitoring system comprising:

a first contact and a second contact configured to engage with the conductive section of the barrel when the barrel is coupled to the actuator; and

an electrical interpreter coupled to the first and second contacts and configured to determine whether the conductive section of the barrel is engaging the first and second contacts to form a closed circuit.

2. The fire suppression system of claim 1, wherein the canister monitoring system further comprises a notifier coupled to the electrical interpreter and configured to provide a notification to an operator in response to determining that an open circuit has been formed between the first and second contacts.

3. The fire suppression system of claim 1, wherein the barrel includes a neck that is received by the actuator when the barrel is coupled to the actuator, and wherein the neck defines the conductive section.

4. The fire suppression system of claim 3, wherein the neck includes a first threaded section defining a plurality of threads, wherein the first threaded section engages a corresponding second threaded section of the actuator to couple the cartridge to the actuator, and wherein at least one of the first and second contacts is in threaded engagement with at least one of the threads.

5. The fire suppression system of claim 1, wherein the actuator includes a receiver configured to receive the conductive section of the cartridge to couple the cartridge to the actuator, wherein the receiver is conductive, and wherein the receiver is the second contact.

6. The fire suppression system of claim 5, wherein the actuator further comprises an isolator coupled to the receiver and the first contact, and wherein the isolator is configured to electrically decouple the first contact from the receiver.

7. The fire suppression system of claim 6, further comprising a biasing element coupled to the isolator, wherein the first contact is translatably coupled to the isolator, and wherein the biasing element is configured to bias the first contact into engagement with the barrel.

8. The fire suppression system of claim 1, further comprising a biasing member configured to bias at least one of the first and second contacts into engagement with the barrel.

9. The fire suppression system of claim 1, wherein the canister monitoring system further comprises a resistor coupled to one of the first and second contacts such that the closed circuit is formed by the electrical interpreter, the first contact, the conductive segment, the second contact, and the resistor when the canister is coupled to the actuator.

10. The fire suppression system of claim 1, wherein the barrel is a first barrel, the conductive section is a first conductive section, and the actuator is a first actuator, the fire suppression system further comprising:

a second cartridge configured to contain a pressurized drive gas, the second cartridge comprising a second electrically conductive section; and

a second actuator selectively coupled to the second cartridge;

wherein the cartridge monitoring system further comprises third and fourth contacts configured to engage with the second conductive section of the second cartridge when the second cartridge is coupled to the second actuator; and is

Wherein the second contact is coupled to the third contact such that the closed circuit is formed by the first contact, the first conductive section, the second contact, the third contact, the second conductive section, and the fourth contact when the first barrel is coupled to the first actuator and the second barrel is coupled to the second actuator.

11. The fire suppression system of claim 1, wherein determining whether the conductive section of the barrel is engaging the first and second contacts to form the closed circuit comprises:

supplying a voltage across the first contact and the second contact such that when the closed circuit is formed, current flows through the first contact, the conductive section, and the second contact; and

monitoring the current to determine if the barrel is engaging the first contact and the second contact.

12. The fire suppression system of claim 11, further comprising a resistor having a variable resistance electrically coupled between the electrical interpreter and the first contact, wherein the electrical interpreter is configured to perform an action in response to a resistance of the resistor falling within a predetermined range.

13. An actuator, comprising:

a receptacle defining a recess configured to receive a neck of a cartridge containing pressurized gas;

an activation mechanism configured to selectively release the pressurized gas from the cartridge such that the pressurized gas flows through the recess and out of the actuator; and

a contact configured to engage the neck when the neck is inserted into the recess, wherein the contact is configured to electrically couple the neck to an electrical interpreter when the contact is engaged with the neck.

14. The actuator of claim 13, further comprising a spacer extending between the contact and the receiver, wherein the spacer electrically decouples the contact from the receiver, wherein the receiver is configured to electrically couple the neck to the electrical interpreter when the receiver is engaged with the neck such that a closed circuit is formed by the contact, the neck, and the receiver when the neck is inserted into the recess of the receiver.

15. The actuator of claim 14, further comprising:

a contact body coupled to the isolator, the contact body defining a contact recess that receives the contact, wherein the contact is translatable along a length of the contact recess; and

a spring positioned within the contact recess and configured to bias the contact toward the recess of the receiver.

16. The actuator of claim 15, wherein the recess of the receiver is configured to receive the neck along a longitudinal axis, and wherein the spring is configured to apply a biasing force to the contact that is substantially perpendicular to the longitudinal axis.

17. The actuator of claim 15, further comprising:

a first terminal configured for electrical coupling to the electrical interpreter, the first terminal being electrically coupled to the contact through the contact body; and

a second terminal configured for electrical coupling to the electrical interpreter, the second terminal electrically coupled to the receiver,

wherein the isolator extends between the first terminal and the second terminal.

18. The actuator of claim 17, further comprising a fastener in threaded engagement with the contact body, wherein the first terminal extends between the fastener and the isolator; and is

Wherein the isolator defines a shoulder, and wherein the second terminal extends between the shoulder and the receiver.

19. A method of monitoring installation of a cartridge, the method comprising:

providing an actuator configured to couple to the cartridge, wherein the actuator is configured to control a flow of material from the cartridge when the cartridge is coupled to the actuator;

positioning a first contact and a second contact such that an electrically conductive portion of the cartridge engages both the first contact and the second contact when the cartridge is coupled to the actuator;

applying a voltage across the first contact and the second contact;

measuring a current through the first contact and the second contact;

determining whether the measured current is below a threshold current; and

providing a notification indicating that the cartridge is not coupled to the actuator in response to determining that the measured current is below the threshold current.

20. The method of claim 19, wherein the actuator includes a receiver defining a recess configured to receive the conductive portion of the cartridge to couple the cartridge to the actuator, wherein the first contact is coupled to the recess, and wherein the second contact is the receiver.

Background

Fire suppression systems are commonly used to protect an area and objects within the area from a fire. The fire suppression system may be activated manually or automatically in response to an indication that a fire is present nearby (e.g., an ambient temperature rise above a predetermined threshold, etc.). Once activated, the fire suppression system spreads the fire suppressant throughout the area. The fire suppressant then extinguishes or controls the fire (e.g., prevents the fire from growing).

Disclosure of Invention

At least one embodiment relates to a fire suppression system. The fire suppression system includes: a tank configured to hold a fire suppressant; a cartridge configured to contain a pressurized drive gas, the cartridge comprising an electrically conductive section; an actuator coupled to the canister and selectively coupled to the cartridge; and a cartridge monitoring system coupled to the actuator. The actuator is configured to selectively supply the pressurized drive gas from the cartridge to the canister to thereby fire suppressant the fire suppressant from the canister. The cartridge monitoring system comprises: (a) a first contact and a second contact configured to engage with the conductive section of the barrel when the barrel is coupled to the actuator; and (b) an electrical interpreter coupled to the first and second contacts and configured to determine whether the conductive section of the barrel is engaging the first and second contacts to form a closed circuit.

Another embodiment relates to an actuator, comprising: a receptacle defining a recess configured to receive a neck of a cartridge containing pressurized gas; an activation mechanism configured to selectively release the pressurized gas from the cartridge such that the pressurized gas flows through the recess and out of the actuator; and a contact configured to engage with the neck when the neck is inserted into the recess. The contact is configured to electrically couple the neck to an electrical interpreter when the contact is engaged with the neck.

Another embodiment relates to a method of monitoring installation of a cartridge. The method comprises the following steps: providing an actuator configured to couple to the cartridge; positioning a first contact and a second contact such that an electrically conductive portion of the cartridge engages both the first contact and the second contact when the cartridge is coupled to the actuator; applying a voltage across the first contact and the second contact; measuring a current through the first contact and the second contact; determining whether the measured current is below a threshold current; and providing a notification indicating that the cartridge is not coupled to the actuator in response to determining that the measured current is below the threshold current. The actuator is configured to control a flow of material from the cartridge when the cartridge is coupled to the actuator.

This summary is illustrative only and is not intended to be in any way limiting. Other aspects, inventive features, and advantages of the devices or processes described herein will become apparent in the detailed description set forth herein when taken in conjunction with the drawings, in which like numerals represent like elements.

Drawings

Fig. 1 is a schematic view of a fire suppression system according to an exemplary embodiment.

FIG. 2 is a schematic view of a canister monitoring system of the fire suppression system of FIG. 1.

Fig. 3 is a perspective view of a connection between an actuator and a canister of a fire suppression system according to an exemplary embodiment.

Fig. 4 is a perspective view of the actuator of fig. 3.

Fig. 5 is a cross-sectional view of the connection between the actuator and the barrel of fig. 3.

Fig. 6 is a perspective view of a connection between an actuator and a canister of a fire suppression system according to another exemplary embodiment.

Fig. 7 is a perspective view of the actuator of fig. 6.

Fig. 8-11 are cross-sectional views of a connection between an actuator and a canister of a fire suppression system according to various exemplary embodiments.

FIG. 12 is a schematic diagram of a cartridge monitoring system of a fire suppression system according to an exemplary embodiment.

Fig. 13 is a cross-sectional view of a connection between an actuator and a cartridge, the actuator including a connector assembly, according to an exemplary embodiment.

Fig. 14 is a perspective view of the connector assembly of fig. 13.

Fig. 15 is a side view of the connector assembly of fig. 13.

Fig. 16 is a front view of the connector assembly of fig. 13.

Fig. 17 is another perspective view of the connector assembly of fig. 13.

Detailed Description

Before turning to the figures, which illustrate exemplary embodiments in detail, it is to be understood that the disclosure is not limited to the details or methodology set forth in the description or illustrated in the figures. It is also to be understood that the terminology used herein is for the purpose of description only and should not be regarded as limiting.

SUMMARY

Some fire suppression systems (e.g., chemical fire suppression systems) include a canister with a fire suppressant, a canister with a drive gas, and an actuator. The actuator controls the flow of drive gas to the canister. When the driving gas is free to flow to the tank, the driving gas forces the fire suppressant out of the tank and onto and/or around the fire. The installation of the cartridge into the system is typically performed near the end of the commissioning process of the fire suppression system. Thus, an operator may forget to install the cartridge when commissioning the system. Without the cartridge, the fire suppression system would not function.

According to an exemplary embodiment, a fire suppression system includes a canister filled with a fire suppressant and a canister filled with a pressurized driving gas. An actuator is fluidly coupled to the canister, and the cartridge may be selectively coupled to the actuator. An automatic activation system (such as a temperature sensitive fusible link) and a manual activation system (such as a manual button or lever) are configured to provide an indication to the actuator in the event of a nearby fire. In response to receiving such an indication, the actuator is configured to fluidly couple the cartridge to the canister. This allows the driving gas from the canister to force the fire suppressant out of the canister. The fire suppressant then flows to a series of nozzles that direct the fire suppressant onto the fire, thereby suppressing the fire.

In some cases, such as during initial installation of the fire suppression system or when resetting the fire suppression system after operation, it is necessary to install a cartridge with a driving gas. However, this step is typically performed near the end of the installation process, and there may be some possibility that the operator may forget to install the cartridge. If the cartridge is not installed properly, the fire suppression system will not function. To avoid this, the fire suppression system includes a cartridge monitoring system configured to determine whether the cartridge is fully engaged with the actuator.

The barrel has a neck defining a male thread section that engages a corresponding female thread section of the actuator. To couple the cartridge to the actuator, the male threaded section is inserted into the female threaded section and the cartridge is rotated until fully engaged. The neck of the barrel is made of an electrically conductive material, such as steel or aluminum. At least one electrical contact extends through the female threaded section of the actuator and engages the male threaded section of the barrel. In some embodiments, the portion of the actuator that receives the neck of the barrel is electrically conductive and serves as the second contact. The electrical interpreter and the power supply provide a voltage across the contacts. The contacts are typically electrically isolated from each other so that when the cartridge is removed, the amount of current flowing between the contacts is negligible. However, when the barrel is fully engaged with the actuator, the contacts engage the conductive neck and current flows through the first contact and the neck and out through the second contact. The electrical interpreter monitors the current. When the current indicates that there is an open circuit across the contacts, the electrolytic release activates an alarm or provides another type of indication to inform the operator that the cartridge is not fully seated or that the cartridge is not present.

Fire suppression system

Referring to fig. 1, a fire suppression system 10 according to an exemplary embodiment is shown. In one embodiment, the fire suppression system 10 is a chemical fire suppression system. The fire suppression system 10 is configured to spray or disperse a fire suppressant onto and/or near a fire to suppress the fire and prevent the spread of the fire. The fire suppression system 10 may be used alone or in combination with other types of fire suppression systems (e.g., building sprinkler systems, hand-held fire extinguishers, etc.). In some embodiments, multiple fire suppression systems 10 are used in combination with one another to cover a larger area (e.g., each of the different rooms of a building).

The fire suppression system 10 may be used in a variety of different applications. Different applications may require different types of fire suppressants and different levels of flowability. The fire suppression system 10 may be used with a variety of different fire suppressants, such as powders, liquids, foams, or other fluid or flowable materials. The fire suppression system 10 may be used in a variety of stationary applications. For example, the fire suppression system 10 may be used in a kitchen (e.g., for a cooking oil or grease fire, etc.), a library, a data center (e.g., for an electronic fire, etc.), a gas station (e.g., for a gasoline or propane fire, etc.), or other stationary application. Alternatively, the fire suppression system 10 may be used in a variety of mobile applications. For example, the fire suppression system 10 may be incorporated into a land-based vehicle (e.g., a racing car, a forestry vehicle, an engineering vehicle, an agricultural vehicle, a mining vehicle, a passenger vehicle, a trash vehicle, etc.), an air vehicle (e.g., a jet plane, an airplane, a helicopter, etc.), or a water vehicle (e.g., a ship, a submarine, etc.).

Referring again to fig. 1, the fire suppression system 10 includes a fire suppressant tank 12 (e.g., a vessel, container, vat, bucket, canister, or tank, etc.). The fire suppressant tank 12 defines (e.g., partially, completely, etc.) an interior volume 14 filled with fire suppressant. In some embodiments, the fire suppressant is generally not pressurized (e.g., near atmospheric pressure). Fire suppressant tank 12 includes an exchange section shown as neck 16. The neck 16 allows drive gas to flow into the interior volume 14 and fire suppressant to flow out of the interior volume 14 so that fire suppressant may be supplied to the fire.

The fire suppression system 10 further includes a cartridge 20 (e.g., a vessel, container, vat, bucket, tank, canister, or tank, etc.). The cartridge 20 defines an interior volume 22 configured for containing a volume of pressurized drive gas. The driving gas may be an inert gas. In some embodiments, the driving gas is air, carbon dioxide, or nitrogen. The cartridge 20 includes an outlet portion or outlet section, shown as a neck 24. The neck 24 defines an outlet fluidly coupled to the internal volume 22. Thus, the drive gas may exit the barrel 20 through the neck 24. The cartridge 20 may be rechargeable or disposable after use. In some embodiments where the cartridge 20 is rechargeable, additional drive gas may be supplied to the internal volume 22 through the neck 24.

The fire suppression system 10 further includes a valve, piercing device, or activator assembly shown as an actuator 30. The actuator 30 includes a receptacle, shown as receptacle 32, configured to receive the neck 24 of the cartridge 20. Neck 24 is selectively coupled to receiver 32 (e.g., by a threaded connection, etc.). Decoupling the cartridge 20 from the actuator 30 facilitates removal and replacement of the cartridge 20 when the cartridge 20 is emptied. The actuator 30 is fluidly coupled to the neck 16 of the fire suppressant tank 12 by a conduit or pipe, shown as a hose 34.

The actuator 30 includes an activation mechanism 36 configured to selectively fluidly couple the interior volume 22 to the neck 16. In some embodiments, activation mechanism 36 includes one or more valves that selectively fluidly couple interior volume 22 to hose 34. These valves may be actuated mechanically, electrically, manually, or otherwise. In some such embodiments, the neck 24 includes a valve that selectively prevents the flow of drive gas through the neck 24. Such a valve may be manually operated (e.g., by a lever or knob on the exterior of the barrel 20, etc.) or may be automatically opened when the neck 24 is engaged with the actuator 30. Such a valve facilitates removal of the cartridge 20 prior to evacuation of the drive gas. In other embodiments, the cartridge 20 is sealed and the activation mechanism 36 includes a pin, knife, staple, or other sharp object that the actuator 30 forces into contact with the cartridge 20. Such sharp objects pierce the outer surface of the barrel 20, fluidly coupling the interior volume 22 with the actuator 30. In some embodiments, activation mechanism 36 pierces cartridge 20 only when actuator 30 is activated. In some such embodiments, activation mechanism 36 omits any valves that control the flow of drive gas to hose 34. In other embodiments, activation mechanism 36 automatically pierces cartridge 20 when neck 24 is engaged with actuator 30.

Once the actuator 30 is activated and the cartridge 20 is fluidly coupled to the hose 34, drive gas from the cartridge 20 is free to flow through the neck 24, the actuator 30, and the hose 34 and into the neck 16. The drive gas forces fire suppressant from fire suppressant tank 12 out through neck 16 and into a conduit or hose, shown as line 40. In one embodiment, the neck 16 directs the drive gas from the hose 34 to the top portion of the internal volume 14. The neck 16 defines an outlet near the bottom of the fire suppressant tank 12 (e.g., using a siphon tube or the like). The pressure of the drive gas at the top of the interior volume 14 forces the fire suppressant out through the outlet and into the conduit 40. In other embodiments, the drive gas enters an airbag within the fire suppressant tank 12, and the airbag presses against the fire suppressant to force the fire suppressant out through the neck 16. In still other embodiments, the piping 40 and the hose 34 are coupled to the fire suppressant tank 12 at different locations. For example, hose 34 may be coupled to the top of fire suppressant tank 12, and piping 40 may be coupled to the bottom of fire suppressant tank 12. In some embodiments, the fire suppressant tank 12 includes a bursting disk that prevents the fire suppressant from flowing out through the neck 16 before the pressure within the interior volume 14 exceeds a threshold pressure. Once the pressure exceeds the threshold pressure, the burst disk ruptures, allowing the fire suppressant to flow. Alternatively, fire suppressant tank 12 may comprise a valve, piercing device, or another type of opening device or activator assembly configured to fluidly couple interior volume 14 to conduit 40 in response to the pressure within interior volume 14 exceeding a threshold pressure. Such an opening device may be configured for mechanical activation (e.g., pressure activates the opening device, etc.), or the opening device may include a separate pressure sensor in communication with the interior volume 14 that activates the opening device.

The piping 40 is fluidly coupled to one or more outlets or sprinklers (e.g., nozzles, sprinkler heads, etc.), shown as nozzles 42. The fire suppressant flows through the conduit 40 and to the nozzle 42. The nozzles 42 each define one or more apertures through which the fire suppressant exits, thereby forming a spray of fire suppressant that covers the desired area. The spray from the nozzle 42 then suppresses or extinguishes the fire in that area. The orifices of the nozzles 42 may be shaped to control the spray pattern of the fire suppressant exiting the nozzles 42. The nozzle 42 may be aimed such that the spray covers a particular point of interest (e.g., a particular piece of restaurant equipment, a particular component within the engine compartment of a vehicle, etc.). The nozzles 42 may be configured such that all nozzles 42 are activated at the same time, or the nozzles 42 may be configured such that only nozzles 42 in the vicinity of a fire are activated.

Fire suppression system 10 further includes an automatic activation system 50 that controls the activation of actuator 30. The automatic activation system 50 is configured to monitor one or more conditions and determine whether the conditions indicate a nearby fire. Upon detection of a nearby fire, the automatic activation system 50 activates the actuator 30, thereby causing the fire suppressant to exit the nozzle 42 and extinguish the fire.

In some embodiments, the actuator 30 is mechanically controlled. As shown in fig. 1, the automatic activation system 50 includes a mechanical system that includes a tensile member (e.g., a rope, cable, etc.), shown as a cable 52, that applies a tensile force to the actuator 30. In the absence of this tensile force, the actuator 30 would activate. The cable 52 is coupled to a fusible link 54, which in turn is coupled to a stationary object (e.g., a wall, floor, etc.). The fusible link 54 comprises two plates held together with a solder alloy having a predetermined melting point. The first plate is coupled to the cable 52 and the second plate is coupled to the stationary object. When the ambient temperature around the fusible link 54 exceeds the melting point of the solder alloy, the solder melts, separating the two plates. This releases the tension on the cable 52 and the actuator 30 activates. In other embodiments, the automatic activation system 50 is another type of mechanical system that applies a force to the actuator 30 to activate the actuator 30. The automatic activation system 50 may include linkages, motors, hydraulic or pneumatic components (e.g., pumps, compressors, valves, cylinders, hoses, etc.), or other types of mechanical components configured to activate the actuator 30. Certain components of the automatic activation system 50 (e.g., compressors, hoses, valves, and other pneumatic components, etc.) may be shared with other portions of the fire suppression system 100 (e.g., the manual activation system 60), and vice versa.

Additionally or alternatively, actuator 30 may be configured to activate in response to receiving an electrical signal from automatic activation system 50. Referring to fig. 1, the automatic activation system 50 includes a controller 56 that monitors signals from one or more fire detectors or sensors (e.g., thermocouples, resistance temperature detectors, etc.), shown as temperature sensors 58. The controller 56 may use the signal from the temperature sensor 58 to determine whether the ambient temperature has exceeded a threshold temperature. Upon determining that the ambient temperature has exceeded the threshold temperature, the controller 56 provides an electrical signal to the actuator 30. The actuator 30 is then activated in response to receiving the electrical signal.

Fire suppression system 10 further includes a manual activation system 60 that controls the activation of actuator 30. Manual activation system 60 is configured to activate actuator 30 in response to an input from an operator. A manual activation system 60 may be included instead of or in addition to the automatic activation system 50. Both automatic activation system 50 and manual activation system 60 may independently activate actuator 30. For example, automatic activation system 50 may activate actuator 30 regardless of any input from manual activation system 60, and vice versa.

As shown in fig. 1, manual activation system 60 includes a mechanical system that includes a tensile member (e.g., a rope, cable, etc.) shown as cable 62 coupled to actuator 30. The cable 62 is coupled to a human interface device (e.g., a button, lever, switch, knob, pull-tab, etc.) shown as a button 64. The button 64 is configured to apply a tensile force to the cable 62 when pressed, and the tensile force is transmitted to the actuator 30. The actuator 30 is activated when subjected to a tensile force. In other embodiments, manual activation system 60 is another type of mechanical system that applies a force to actuator 30 to activate actuator 30. Manual activation system 60 may include linkages, motors, hydraulic or pneumatic components (e.g., pumps, compressors, valves, cylinders, hoses, etc.), or other types of mechanical components configured to activate actuator 30.

Additionally or alternatively, actuator 30 may be configured to activate in response to receiving an electrical signal from manual activation system 60. As shown in fig. 1, the button 64 is operatively coupled to the controller 56. The controller 56 may be configured to monitor the status (e.g., engaged, disengaged, etc.) of the human interface device or user input device. Upon determining that the human interface device is engaged, the controller provides an electrical signal to activate the actuator 30. For example, the controller 56 may be configured to monitor the signal from the button 64 to determine whether the button 64 is pressed. Upon detecting that the button 64 has been pressed, the controller 56 sends an electrical signal to the actuator 30 to activate the actuator 30.

The automatic activation system 50 and the manual activation system 60 are shown as activating the actuator 30 both mechanically (e.g., although tensile force is applied by cable, by applying pressurized liquid, by applying pressurized gas, etc.) and electrically (e.g., by providing an electrical signal). However, it should be understood that automatic activation system 50 and/or manual activation system 60 may be configured to activate actuator 30 only mechanically, only electrically, or some combination of the two. For example, the automatic activation system 50 may omit the controller 56 and activate the actuator 30 based on input from the fusible link 54. By way of another example, the automatic activation system 50 may omit the fusible link 54 and use input from the controller 56 to activate the actuator 30.

Cartridge monitoring system

Referring to fig. 1 and 2, the fire suppression system 10 further includes a cartridge monitoring system 100. The cartridge monitoring system 100 is configured to detect whether the cartridge 20 is engaged with the actuator 30. In response to detecting that cartridge 20 is not engaged with actuator 30, cartridge monitoring system 100 provides a notification to an operator. The cartridge monitoring system 100 prevents the fire suppression system 10 from accidentally missing a cartridge 20, which would prevent the fire suppression system 10 from functioning properly.

Referring to fig. 2, the cartridge monitoring system 100 includes a pair of electrical contacts (shown as contacts 102 and 104) coupled to the actuator 30. The contacts 102 and 104 extend through the receiver 32 of the actuator 30. When the barrel 20 is fully engaged with the receiver 32, the contacts 102 and 104 are positioned to engage the neck 24 of the barrel 20. In some embodiments, the neck 24 is made of an electrically conductive material (e.g., steel, aluminum, brass, etc.). In other embodiments, the neck 24 is made of a non-conductive or insulating material, and an additional conductor, such as a conductive sleeve, is added to the neck 24. Thus, when the neck 24 is fully engaged with the receiver 32, the contact 102 is electrically coupled to the contact 104 through and to the electrically conductive portion of the neck 24.

The cartridge monitoring system 100 further includes a controller or circuit shown as an electrolytic discharger 110. The electrical interpreter 110 is configured to control the operation of the other elements of the cartridge monitoring system 100. The electrical interpreter 110 is electrically coupled to the contact 102 by a conductor or lead, shown as wire 112, and to the contact 104 by a conductor or lead, shown as wire 114. Wires 112 and 114 help to place electrical interpreter 110 at a location remote from actuator 30. The wires 112 and 114 may each include one or more individual conductors. In other embodiments, the wires 112 and 114 are omitted and the electrical interpreter 110 is coupled directly to the contacts 102 and 104. In some embodiments, one of the wires is directly connected to receiver 32, and receiver 32 serves as one of the contacts.

In some embodiments, the electrolysis release 110 is or includes a controller. The controller may include a processor and a memory. For example, the controller may be configured to monitor the status of an input (e.g., current flowing through the contacts 102 and 104) and issue a command to another component (e.g., the alarm 118) based on the status of the input. In other embodiments, the controller is omitted and the electrical interpreter 110 includes basic electronic components. By way of example, electrointerpreter 110 may be a series of wires that route electrical energy from a battery (e.g., power source 116) to a light source (e.g., alarm 118) when a switch (e.g., circuit 120) coupled to electrical interpreter 110 is closed (e.g., neck 24 is engaged with contacts 102 and contacts 104).

The electrical interpreter 110 is operatively coupled to a power source 116. The power source 116 is configured to generate or deliver electrical energy to the electrolysis release 110 to power the cartridge monitoring system 100. The power supply 116 may be an Alternating Current (AC) power supply or a Direct Current (DC) power supply. By way of example, power source 116 may be a cable that transfers electrical energy from the power grid to electrodischarger 110. By way of another example, the power source 116 may be a battery or a capacitor.

The electrical interpreter 110 is also operatively coupled to a notification device, indicator, or notifier, shown as an alarm 118. The alarm 118 is configured to provide notifications (e.g., information, instructions, etc.) to an operator. The alarm 118 may be or include a light source (e.g., a Light Emitting Diode (LED), an incandescent bulb, etc.) that provides light as a notification. The alarm 118 may be or include a speaker that emits a sound as a notification. The alarm 118 may be or include a display (e.g., a liquid crystal display, a dot matrix display, etc.) that displays a message as a notification. The alarm 118 may be or include a motor that rotates a weight to vibrate or move a sign or some other object between two positions as a notification. The alarm 118 may be or include a controller operatively coupled to a network and configured to provide a text message, a telephone call, an email, or another type of notification to a user device (e.g., a smartphone, a laptop computer, etc.) over the network. The alarm 118 may also communicate with and provide information (e.g., notifications) to a larger network or system (e.g., a building maintenance system). The system may then store the information and/or act in response to the information (e.g., provide a notification to a user of the larger system).

The electrical interpreter 110 is configured to determine whether the electrical circuit between the contacts 102 and 104 is open or closed. Specifically, using electrical energy from power source 116, electrolyzer 110 is configured to apply a voltage across wires 112 and 114 and thus across contacts 102 and contacts 104. When the neck 24 is fully engaged with the receiver 32, the neck 24 engages both the contact 102 and the contact 104. This completes the circuit 120, which includes the electrical interpreter 110, the wire 112, the contact 102, the conductive portion of the neck 24, the contact 104, and the wire 114. Thus, current flows through the circuit 120. The electrical interpreter 110 monitors the current and when the current is above a threshold current (e.g., indicating a closed circuit), the electrical interpreter 110 does not activate the alarm 118. When the current is below a threshold current (e.g., indicating an open circuit), the electroreleaser 110 may activate the alarm 118 to indicate that the cartridge 20 is not coupled (e.g., not fully engaged) with the actuator 30. Alternatively, the electroreleaser 110 may activate the alarm 118 to provide notification to the operator that the cartridge 20 is fully engaged when the supplied current is above the threshold current.

When the barrel 20 is disengaged from the receiver 32, the neck 24 is disengaged from both the contact 102 and the contact 104. Thus, the contact 102 and the contact 104 are electrically isolated and no current flows through the contact 102 and the contact 104 or a current flow through both contacts is negligible. The electrical interpreter 110 monitors the supplied current and when the current is below a threshold current (e.g., indicating an open circuit), the electrical interpreter 110 activates an alarm 118 to provide notification to an operator that the cartridge 20 is not fully engaged. Such notification may be provided when cartridge 20 is only partially engaged with actuator 30 (e.g., when only a single thread of neck 22 is engaged with receiver 32) and/or when cartridge 20 is not engaged at all with actuator 30 (e.g., the cartridge is not present, etc.). The cartridge monitoring system 100 may provide different notifications for different levels of engagement (e.g., fully engaged, partially engaged, etc.). For example, one notification may be to illuminate a first light and another notification may be to illuminate a second light.

Alternatively, electrodischarger 110 may be used as a constant current source that supplies a variable voltage across wires 112 and 114. The constant current source controls the voltage so that a constant current is supplied through the wires 112 and 114. In such embodiments, the electrodischarger 110 may be configured to not activate the alarm 118 when a closed circuit is detected and to activate the alarm 118 when an open circuit is detected.

In one embodiment, the contacts 102 and 104 are made of gold or are gold plated such that the surfaces of the contacts 102 and 104 that engage the neck 24 are gold. Gold is generally considered a good conductor and is inherently corrosion resistant. The corrosion build-up on the contacts 102 and 104 may interfere with the electrical connection between the contacts 102, 104 and the conductive portion of the neck 24 such that the electrolysis release 110 erroneously determines that the cartridge 20 is not fully engaged with the actuator 30. In embodiments where the contacts 102 and 104 are made of a different material than the neck 24, the corrosion resistance of gold is particularly desirable because contact between dissimilar metals may accelerate corrosion. In other embodiments, the contacts 102 and 104 are made of other materials (e.g., copper, brass, aluminum, steel, carbon, etc.).

In some embodiments, a resistive element (e.g., a resistor or group of resistors), shown as resistive element 122, is included in series along the length of wire 112 and/or wire 114. Thus, resistive element 122 is part of circuit 120. In some embodiments, resistive element 122 comprises a single resistor. In other embodiments, resistive element 122 includes multiple resistors connected in parallel or in series. The resistive element 122 may be sized (e.g., the resistance of the resistive element 122 may be selected, resistors may be added or removed, etc.) to adjust the current flowing through the circuit 120 or the voltage drop across the resistive element 122 when the cartridge 20 is fully engaged. Increasing the resistance of resistive element 122 decreases the current flowing through circuit 120 for a given applied voltage. Reducing the current flowing through the circuit 120 may reduce the amount of electrical energy that is converted and dissipated as heat, thereby potentially preventing damage to components of the circuit 120 and reducing energy waste. Alternatively, in embodiments where the electrolyzer 110 supplies a constant current, adjusting the resistance of the resistive element 122 may control the voltage drop across the resistive element 122.

In some embodiments, the circuit 120 includes components (e.g., switches, etc.) configured to change the resistance of the resistive element 122 in response to certain events. These events may include detection of an open circuit (e.g., caused by a wire break, etc.), detection of a ground fault, activation of a manual device (e.g., push button, etc.), activation of an automatic device such as a sensor (e.g., temperature or thermal sensor, optical sensor, etc.), or other event. The circuit 120 may change the resistance of a single resistor, add or remove resistors to or from the resistive element 122, or change the arrangement of resistors within the resistive element 122 to change the resistance of the resistive element 122. Under nominal conditions (e.g., cartridge 20 fully engaged with actuator 30 and no fault, etc.), resistive element 122 has a predetermined resistance (e.g., 4700 ohms, etc.). For each event that occurs, the circuit 120 is configured to change the resistance of the resistive element 122 to a different predetermined resistance or within a different predetermined resistance band that specifically corresponds to the event.

Electrical interpreter 110 is configured to measure the resistance of resistive element 122. By way of example, electrodischarger 110 may comprise a microprocessor having an analog/digital interface that measures the voltage drop across resistive element 122. In embodiments where a constant current is supplied to the circuit 120, the voltage drop across the resistive element 122 and the supplied current may be used to determine the resistance of the resistive element 122. In embodiments where the voltage supplied across circuit 120 is known and the resistance of each component other than resistive element 122 is known, the current through circuit 120 may be used to determine the resistance of resistive element 122. For example, a secondary resistor having a known resistance may be added to circuit 120 in series with resistive element 122. The analog/digital interface may measure the voltage across the secondary resistor to determine the current through the circuit 120. Once the resistance of the resistive element 122 has been determined, the electrointerpreter 110 may compare the measured resistance of the resistive element 122 to a list of predetermined resistances or a list of predetermined resistance bands (e.g., stored in the memory of the controller) corresponding to each event to identify which event is currently occurring. The electrical interpreter 110 may be configured to subsequently perform an action based on the event that occurred (e.g., provide a notification through the alarm 118, etc.).

Referring to fig. 3-11, a connection between neck 24 and receiver 32 is shown, according to various exemplary embodiments. The receiver 32 defines a channel, aperture or recess 130 that receives the neck 24 of the cartridge 20. Recess 130 is defined between an annular sidewall 132 and a flat end wall 134 of receiver 32. Recess 130 is fluidly coupled to the interior of actuator 30 such that the drive gas flows from the interior volume 22 of cartridge 20 and through recess 130 before entering hose 34. The neck 24 includes a threaded section 136 having a series of external male threads, and the receiver 32 includes a threaded section 138 having a corresponding series of internal female threads. The threaded section 138 of the receiver 32 is defined by the annular sidewall 132. Fig. 3, 5, and 7 illustrate the thread section 136 and the thread section 138 prior to cutting the threads, however, separate threads (e.g., thread 170 and thread 172) are shown in fig. 8-11.

In fig. 3, 5 and 7, neck 24 is fully engaged with receiver 32. To fully engage, the neck 24 is tightened (e.g., rotated) into the receiver 32 until a threshold torque is applied to the neck 24. Threaded section 136 and threaded section 138 are pressed against each other to move neck 24 and receiver 32 together. As a result of applying this threshold torque, the neck 24 presses against the receiver 32 with sufficient force to form a seal and prevent leakage of the drive gas. A seal, shown as a gasket 140, may be placed around the neck 24 between the flat surface 142 of the cartridge 20 and the flat surface 144 of the receiver 32. The planar surface 142 and the planar surface 144 are annular and continuous (e.g., the planar surface 142 and the planar surface 144 surround the neck 24). The liner 140 may be made of a compliant material (e.g., rubber, plastic, etc.). In some embodiments, the gasket 140 is flat and annular (e.g., a washer) in its free or uncompressed state. When a threshold torque is applied to the neck 24, the liner 140 is compressed between the flat surface 142 and the flat surface 144. The gasket 140 compresses and acts as a seal between the flat surface 142 and the flat surface 144 to prevent leakage of the drive gas. In addition, the gasket 140 acts as a spring to bias the threaded section 136 relative to the threaded section 138 such that friction between the threaded section 136 and the threaded section 138 prevents the connection between the neck 24 and the receiver 32 from being inadvertently loosened. The liner 140 also limits the transmission of vibrations between the neck 24 and the receiver 32.

Referring to fig. 3-7, the contacts 102 and 104 extend through and are coupled to a body, spacer, or plug, shown as an isolator 150. The separator 150 is made of an electrically insulating material (e.g., plastic, etc.). The isolator 150 separates the contacts 102, 104 from one another, thereby preventing them from contacting one another, which could falsely indicate engagement of the cartridge 20 with the actuator 30. The isolator 150 extends through the aperture defined by the receiver 32 such that the contacts 102 and 104 are exposed to the recess 130. As shown, isolator 150 is coupled to receiver 32 by a threaded connection. In other embodiments, spacer 150 is adhered, fastened, or otherwise connected to receiver 32. In still other embodiments, the isolator 150 is omitted and the contacts 102 and 104 are coupled directly to the receiver 32, wherein the receiver 32 is made of an insulating material to prevent current flow between the contacts. In such embodiments, the receiver 32 may be made of an insulating material to prevent the contacts 102 and 104 from electrically coupling to each other without the barrel 20 being engaged.

The threaded section 138 may also be formed from the contact 102, the contact 104, and/or the isolator 150 (e.g., machining the contact 102, the contact 104, and the isolator 150 to define threads of the threaded section 138). This facilitates full engagement of the cartridge 20 with the actuator 30 without interference from the contacts 102, 104, or the isolator 150. Additionally, this facilitates engagement of the threads of the threaded section 136 with the contact 102 and the contact 104. This ensures a secure electrical connection between the contacts 102, 104 and the neck 24.

The placement of the contacts 102 and 104 varies between different embodiments. When neck 24 is fully engaged with receiver 32, both neck 24 and receiver 32 extend along longitudinal axis 160. In the embodiment shown in fig. 3-5, the contact 102 and the contact 104 are arranged substantially perpendicular to the longitudinal axis 106 such that the contact 102 and the contact 104 are arranged at the same longitudinal position. In this configuration, both the contact 102 and the contact 104 engage the same thread or threads in the threaded section 136. Thus, both the contacts 102 and 104 engage the neck 24 at substantially the same level of engagement of the neck 24 with the receiver 32. The longitudinal position of the contacts 102 and 104 may be varied to adjust the point at which the contacts 102 and 104 engage the neck 24. For example, moving the contacts 102 and 104 up deeper into the receiver 32 requires a greater level of engagement of the neck 24 with the receiver 32 before the contacts 102 and 104 engage the neck 24. In this way, the contacts 102 and 104 may be positioned such that the circuit 120 is completed only when the neck 24 is fully engaged with the receiver 32.

In an alternative embodiment shown in fig. 6 and 7, the contact 102 and the contact 104 are positioned substantially parallel to the longitudinal axis 160 such that the contact 102 is longitudinally offset from the contact 104. As shown in fig. 6 and 7, the contacts 104 are positioned longitudinally deeper into the receptacle 32 than the contacts 102. However, in other embodiments, the contacts 102 are longitudinally positioned deeper into the receptacle 32 than the contacts 104. In the embodiment shown in fig. 6 and 7, the contact 102 engages the neck 24 with a lesser degree of engagement of the neck 24 with the receiver 32 than the contact 104. Thus, the point at which both the contact 102 and the contact 104 engage the neck 24 is driven by the longitudinal position of the contact 104. The longitudinal position of the contact 104 may be varied to adjust the contact 102 and the point at which the contact 104 engages the neck 24. For example, moving the contact 104 up deeper into the receptacle 32 requires a greater level of engagement of the neck 24 with the receptacle 32 before both the contact 102 and the contact 104 engage the neck 24. In this way, the contacts 104 may be positioned such that the circuit 120 is completed only when the neck 24 is fully engaged with the receiver 32.

Referring to fig. 8-11, the thread section 136 includes an external male thread, shown as thread 170, and the thread section 138 includes a corresponding internal female thread, shown as thread 172. The pitch and number of threads 170 and 172 vary between different embodiments. In the embodiment shown in fig. 8 and 9, the contacts 102 and 104 are arranged longitudinally offset from each other, similar to the embodiment shown in fig. 6 and 7. In the embodiment shown in FIG. 8, contact 102 and contact 104 each engage approximately a single one of threads 170. In the embodiment shown in FIG. 9, the contact 102 and the contact 104 each engage a plurality of threads in the threads 170. Engaging the plurality of threads 170 with the contact 102 and the contact 104 increases the surface area of the neck 24 engaged by the contact 102 and the contact 104. This increases the strength of the connection between the contacts 102, 104 and the neck 24, making the barrel monitoring system 100 more corrosion resistant and more resistant to part dimensional changes due to manufacturing.

Referring to fig. 10, the neck 24 defines an annular surface at the end of the barrel 20, shown as end face 174. The end face 174 is flat and does not include any threads 170. The end face 174 extends substantially perpendicular to the longitudinal axis 160. When the neck 24 is received within the recess 130, the end face 174 faces the end wall 134 of the receiver 32. In the embodiment shown in fig. 10, the contacts 102 and 104 extend longitudinally through the end wall 134 of the receptacle 32 and engage the end face 174 of the neck 24. The longitudinal position of the contacts 102 and 104 can be adjusted to control when the contacts 102 and 104 engage the neck 24. In one embodiment, both contacts 102 and 104 engage end wall 134 only when neck 24 is fully engaged with receiver 32.

In some embodiments, the contacts 102 and 104 are biased into engagement with the neck 24. In the embodiment shown in fig. 10, a pair of biasing members, shown as compression springs 180, extend between the contact 102 and the receiver 32 and between the contact 104 and the receiver 32. The compression spring 180 applies a biasing force to longitudinally bias the contacts 102 and 104 into the recesses 130 and thus toward the end face 174. Similarly, a biasing member may be used with the embodiment shown in FIG. 8 to bias the contacts 102 and 104 radially inward into engagement with the threads 170. The biasing member forces engagement between the contacts 102, 104 and the neck 24, thereby improving the robustness of the connection.

The angular position of the contacts 102 and 104 along the outer perimeter of the recess 130 may vary. In the embodiment shown in fig. 6 and 7, the contacts 102 and 104 are located at the same angular position. In the embodiment shown in fig. 10 and 11, the contacts 102 and 104 are diametrically opposed (i.e., offset from each other by 180 degrees). In other embodiments, an angular offset of between 0 and 180 degrees is utilized.

In other embodiments, instead of conducting electrical energy through the neck 24, the circuit 120 is completed by an external conductor (e.g., a conductor that is not part of the barrel 20) when the neck 24 is present in and/or fully engaged with the receptacle 32. By way of example, the surface of the contact 104 shown in fig. 10 that engages the end face 174 may be non-conductive. Conversely, when the neck 24 reaches full engagement with the receiver 32, the end face 174 urges the contact 104 into engagement with an outer conductor (e.g., positioned over the contact 104 as shown in fig. 10, etc.). When neck 24 is present in and/or fully engaged with receptacle 32, electrical energy will then flow through the outer conductor to complete circuit 120.

In some embodiments, a single installation requires multiple cartridges 20, and the cartridges may be arranged in close proximity relative to one another. For example, when the fire suppression system 10 is to cover a large area, the fire suppression capability of the fire suppression system 10 may be enhanced with multiple components each including the fire suppressant tank 12, the canister 20, and the actuator 30. The actuators 30 may each be independent or may all be included in the same housing. In such embodiments, it is desirable to alert the operator if any of the actuators 30 are not fully engaged with the cartridge 20. To accomplish this, multiple circuits 120 may be connected to a single electrical interpreter 110. Electrodischarger 110 may then be configured to trigger alarm 118 if less than a threshold current is detected in any of circuits 120.

Alternatively, as shown in fig. 12, the cartridge monitoring system 100 may be simplified by arranging all of the circuits 120 in series. To do this, the wires 112 and contacts 102 of one circuit 120 are coupled to the wires 114 and contacts 104 of an adjacent circuit 120. The wires 112 and contacts 102 of one circuit 120 are coupled to the wires 114 and contacts 104 of another adjacent circuit 120. This mode continues for all remaining circuits 120. Wires 112 and wires 114, which are not yet connected to another circuit 120, are connected to electrical interpreter 110. In this configuration, if any of the actuators 30 is not fully engaged with the cartridge 20, the electroreleaser 110 will detect an open circuit and activate the alarm 118. One resistive element 122 may be associated with each of the actuators 30. In this case, the resistance of each resistive element 122 may change based on events related to the connection of the corresponding actuator 30 and cartridge 20. Electrical interpreter 110 may utilize a multiplexer or other sampling circuit to sample the voltage across each resistive element 122 using the same analog/digital interface.

In alternative embodiments, the cartridge monitoring system 100 may be used with other types of connectors. For example, the cartridge monitoring system 100 may be used to determine whether a quick disconnect connector is fully engaged. Quick disconnect connectors typically include a male fitting defining an annular groove and a female fitting configured to receive the male fitting. The female coupling includes a series of ball bearings that may be selectively inserted into an annular groove of the male coupling to couple the male and female couplings. In such embodiments, the contact 102 and the contact 104 may be coupled to a female coupling and arranged such that the contact 102 and the contact 104 engage the male coupling when the quick disconnect connector is fully engaged.

Referring to fig. 13-17, according to an exemplary embodiment, actuator 30 includes a switch, shown as contact assembly 200. The contact assembly 200 includes a body or housing (e.g., contact housing, contact body, etc.) shown as a pawl housing 202. The pawl housing 202 is substantially cylindrical and has an externally threaded surface extending along its length. The pawl housing 202 extends through an aperture defined by the isolator 150. Specifically, the externally threaded surface is configured to threadably engage with an internally threaded surface of the isolator 150 to couple the pawl housing 202 to the isolator 150. The pawl housing 202 may define an interface (e.g., a slot, a cruciform recess, a quincunx recess, a series of outer flat faces, etc.) to facilitate the transfer of torque from a tool (e.g., a wrench, a screwdriver, etc.) to the pawl housing 202 during installation of the pawl housing 202 with the isolator 150.

The pawl housing 202 defines a recess (e.g., a contact recess, a spherical pawl recess, a pawl recess, etc.) shown as a spherical recess 204 that extends along the length of the pawl housing 202, wherein the end of the pawl housing 202 that is positioned opposite the cartridge 20 is closed. The pawl housing 202 is positioned such that the spherical recess 204 extends radially relative to the longitudinal axis 160 (e.g., substantially perpendicular to the longitudinal axis 160). The spherical recess 202 receives a biasing element, shown as a spring 206, and a detent, shown as a contact 208 (e.g., a spherical detent, a frustoconical tapered detent, etc.). The spring 206 is positioned between the closed end of the pawl housing 202 and the contact 208 such that the spring 206 biases the contact 208 radially inward toward the longitudinal axis 160 and the barrel 20.

The first electrical conductor, shown as terminal 220, is configured to be coupled (e.g., by wire 112) to electrical interpreter 110. A fastener, shown as a nut 222, is threaded onto the pawl housing 202. In other embodiments, the nut 222 is fixedly coupled to the pawl housing 202. The terminal 220 extends around the pawl housing 202 between the nut 222 and the isolator 202. The terminals 220 may be spade-shaped, hook-shaped, loop-shaped, or other shapes that facilitate such placement of the terminals 220. The nut 222 is tightened to secure the terminal 220 to the nut 222 and the shoulder 152 of the spacer 150, holding the terminal 220 in place.

The contacts 208 function as the contacts 102 described elsewhere herein. Contact 208 is electrically coupled to electrical interpreter 110. Specifically, the terminal 220 is electrically coupled to the contact 208 by: engaging the terminal 220 with the nut 222 and/or the pawl body 202; engaging the nut 222 with the pawl body 202; engaging the pawl body 202 with the spring 206; and engaging the contact 208 with the pawl body 202 and/or the spring 206. Accordingly, the terminal 220, the pawl body 202, the nut 222, the spring 206, and/or the contact 208 may include a conductive material (e.g., a metal such as steel or copper) that facilitates such electrical coupling.

A second electrical conductor, shown as terminal 224, is configured to be coupled to electrical interpreter 110 (e.g., by wire 114). Terminals 224 extend around isolator 150 between shoulder 152 and receiver 32. The terminals 224 may be spade-shaped, hook-shaped, loop-shaped, or other shapes that facilitate such placement of the terminals 224. The spacer 150 is tightened to compress the terminal 224 against the shoulder 152 and the receiver 32, holding the terminal 224 in place.

The receiver 32 serves as the contact 104 described elsewhere herein. Receiver 32 is electrically coupled to electrical interpreter 110 through the engagement of terminals 224 with receiver 32. At least a portion or at least a section of terminals 224 and receivers 32 may include an electrically conductive material that facilitates such electrical coupling. The isolator 150 surrounds the pawl body 202, extending between the receiver 32 and the pawl body 202. The isolator 150 insulates the pawl body 202, thereby electrically decoupling the pawl body 202 from the receiver 32.

To assemble contact assembly 200 with receiver 32, terminal 224 is placed between isolator 150 and receiver 32. The isolator 150 and the pawl body 202 are inserted through the bore 230 defined by the receiver 32 and the isolator 150 is tightened until the shoulder 152 engages the terminal 224 and the terminal 224 engages the receiver 32. The terminals 220 are positioned such that the terminals 220 receive the pawl body 202. The nut 222 is placed on the pawl body 202 and tightened until the nut 222 contacts the terminal 220 and the terminal 220 contacts the shoulder 150.

Before the neck 24 of the cartridge 20 is fully inserted into the recess 130 of the receiver 32, the contact 208 extends into the recess 130. When neck 24 is first inserted, neck 24 engages receiver 32, electrically coupling neck 24 to terminal 224 through receiver 32. When the end of the neck 24 reaches the longitudinal position of the contact 208, the neck 24 engages the contact 208, electrically coupling the neck 24 to the terminal 220 through the contact 208. At this point, therefore, the neck 24 completes the circuit 120. Upon further insertion into the neck 24, the curved surface of the contact 208 presses against the neck 24, forcing the contact 208 to retract into the spherical recess 204. The spring 206 maintains a biasing force to keep the contact 208 pressed against the neck 24. The biasing force of the spring 206 may improve the strength and durability of the connection between the contact 208 and the neck 24 relative to a contact that is fixed in place and not biased against the neck 24.

In other embodiments, the cartridge monitoring system 100 may be used to monitor connections between other types of components. In general, the cartridge monitoring system 100 may be configured to determine whether a first component (e.g., a container, an adapter, a catheter, a pump, an actuator, etc.) is coupled to a second component (e.g., a container, an adapter, a catheter, a pump, an actuator, etc.), where the first component includes a receiver that defines a recess that receives a protrusion (e.g., a neck, a boss, etc.) of the second component. In such an arrangement, the canister monitoring system 100 includes at least one contact extending into the recess to engage with the conductive portion of the protrusion of the second component. In some embodiments, a fluid (e.g., a liquid, a gas, etc.) flows through the receptacle and the protrusion. For example, in some fire suppression systems, the cartridge 20 is omitted and the fire suppressant tank 12 is filled with pressurized drive gas. In such embodiments, cartridge monitoring system 100 may be used to monitor the connection between fire suppressant tank 12 and the actuators that control the flow of fire suppressant from fire suppressant tank 12. In other embodiments, the cartridge monitoring system 100 is configured for use in other industries (e.g., for determining when to connect two hoses, for determining when a tank with breathable air is coupled to a manifold in a medical or diving application, for determining when an air tank is coupled to a paintball marker, etc.).

Configuration of the exemplary embodiment

As used herein, the terms "about," "left-right," "substantially," and similar terms are intended to have a broad meaning consistent with the usual and acceptable use by those of ordinary skill in the art to which the subject matter of this disclosure pertains. Those skilled in the art who review this disclosure will appreciate that these terms are intended to allow a description of certain features described and claimed without limiting the scope of these features to the precise numerical ranges provided. Accordingly, these terms should be understood to indicate that insubstantial or inconsequential modifications or changes in the subject matter described and claimed are considered to be within the scope of the disclosure as set forth in the following claims.

It should be noted that the term "exemplary" and variations thereof as used herein to describe various embodiments are intended to represent possible examples, representations or illustrations of possible embodiments of those embodiments (and such terms are not intended to imply that such embodiments are necessarily extraordinary or best examples).

The term "coupled" and variations thereof as used herein means that two components are joined to each other, either directly or indirectly. Such attachment may be stationary (e.g., permanent or fixed) or movable (e.g., removable or releasable). Such joining may be achieved with the two members being directly coupled to one another, with the two members being coupled to one another using separate intermediate members and any additional intermediate members, or with the two members being coupled to one another using intermediate members that are integrally formed as a single unitary body with one of the two members. If "coupled" or variations thereof are modified by additional terms (e.g., directly coupled), then the general definition of "coupled" provided above is modified by the plain language meaning of the additional terms (e.g., "directly coupled" means the joining of two components without any separate intermediate members), resulting in a narrower definition than the generic definition of "coupled" provided above. Such coupling may be mechanical, electrical, or fluid.

The component positions referred to herein (e.g., "top," "bottom," "above," "below") are merely used to describe the orientation of the various components within the figures. It should be noted that the orientation of the various elements may differ according to other exemplary embodiments, and such variations are intended to be encompassed by the present disclosure.

The hardware and data processing components described in connection with the embodiments disclosed herein to implement the various processes, operations, illustrative logic, logic blocks, modules, and circuits may be implemented or performed with the following designed to perform the functions described herein: a general purpose single-or multi-chip processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA), or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination thereof. A general purpose processor may be a microprocessor, or any conventional processor, controller, microcontroller, or state machine. A processor may also be implemented as a combination of computing devices, such as a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration). In some embodiments, certain processes and methods may be performed by circuitry that is specific to a given function. The memory (e.g., memory unit, storage) may include one or more means (e.g., RAM, ROM, flash memory, hard disk storage, etc.) for storing data and/or computer code for performing or facilitating the various processes, layers, and modules described in this disclosure. The memory may be or include volatile memory or non-volatile memory, and may include database components, object code components, script components, or any other type of information structure for supporting the various activities and information structures described in this disclosure. According to an exemplary embodiment, the memory is communicatively connected to the processor via the processing circuit and includes computer code for performing (e.g., by the processing circuit or the processor) one or more processes described herein.

The present disclosure contemplates methods, systems, and program products on any machine-readable media for performing various operations. Embodiments of the present disclosure may be implemented using an existing computer processor, or by a special purpose computer processor in conjunction with a suitable system for this or another purpose, or by a hardwired system. Embodiments within the scope of the present disclosure include program products comprising machine-readable media for carrying or having machine-executable instructions or data structures stored thereon. Such machine-readable media can be any available media that can be accessed by a general purpose or special purpose computer or other machine with a processor. By way of example, such machine-readable media can comprise RAM, ROM, EPROM, EEPROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to carry or store desired program code in the form of machine-executable instructions or data structures and which can be accessed by a general purpose or special purpose computer or other machine with a processor. Combinations of the above are also included within the scope of machine-readable media. Machine-executable instructions comprise, for example, instructions and data which cause a general purpose computer, special purpose computer, or special purpose processing machines to perform a certain function or group of functions.

Although the figures and descriptions may show a specific order of method steps, the order of the steps may differ from that shown and described unless otherwise indicated above. Two or more steps may also be performed simultaneously or partially simultaneously, unless stated differently above. Such variations may depend, for example, on the software and hardware systems selected and on designer choice. All such variations are within the scope of the present disclosure. Likewise, software implementations of the described methods can be accomplished with standard programming techniques with rule based logic and other logic to accomplish the various connection steps, processing steps, comparison steps and decision steps.

It is important to note that the construction and arrangement of the fire suppression system as shown in the various exemplary embodiments is illustrative only. Additionally, any element disclosed in one embodiment may be combined with or used in any other embodiment disclosed herein. For example, at least the contact assembly 200 of the exemplary embodiment shown in fig. 13 may be incorporated into at least the actuator 30 of the exemplary embodiment shown in fig. 5. While the above describes only one example of an element from one embodiment that may be combined or used with another embodiment that has been described above, it should be understood that other elements of the various embodiments may be combined or used with any other embodiment disclosed herein.