Fire protection system

Abstract

A component 14a for a fire protection system 100 includes communications circuitry configured to communicate with another component 14b-14d of the fire protection system 100. The communications circuitry may allow a portable tool 20 to communicate with the other component 14b-14d via the component 14a.

Claims

1. A component for a fire protection system, the component comprising: first communications circuitry configured to communicate with another component of the fire protection system; and second communication circuitry configured to communicate wirelessly with a portable device of the fire protection system; wherein the first communications circuitry is configured to transmit one or more commands to the other component; wherein the first communications circuitry is configured to receive, in response to the one or more commands, data from the other component; wherein the second communications circuitry is configured to transmit the data to the portable device, wherein the data comprises data relating to at least one of a status and configuration of the other component; wherein the component is configured to communicate with the other component in response to one or more commands received from the portable device; and wherein the component is configured to communicate with one another using a multi-master communications system.

2. The component of claim 1, wherein: the component comprises any one of a fire detector, a smoke detector, a heat detector, a manual call point, a fire alarm, a fire suppression component, a sprinkler, a fire barrier, and a smoke extractor; and the other component comprises any one of a fire detector, a smoke detector, a heat detector, a manual call point, a fire alarm, a fire suppression component, a sprinkler, a fire barrier, and a smoke extractor.

3. A fire protection system comprising: a fire control panel; a plurality of components connected to the fire control panel; and a portable device configured to communicate wirelessly with one or more of the plurality of components; wherein at least one component of the plurality of components comprises the component of claim 1.

4. The fire protection system of claim 3, wherein the plurality of components are connected to the fire control panel by wiring, and wherein the first communications circuitry is configured to communicate with the second component via the wiring.

5. A building comprising the fire protection system claim 3.

6. A fire protection system comprising: a fire control panel; a plurality of components connected to the fire control panel; and a portable device configured to communicate wirelessly with one or more of the plurality of components; wherein the plurality of components comprise a first component and second component; and wherein the first component comprises first communications circuitry configured to communicate with the second component; wherein the first communications circuitry is configured to transmit one or more commands to the second component; wherein the first communications circuitry is configured to receive, in response to the one or more commands, data from the second component; wherein the second communications circuitry is configured to transmit the data to the portable device, wherein the data comprises data relating to at least one of a status and configuration of the second component; wherein the first component is configured to communicate with the second component in response to one or more commands received from the portable device; and wherein the plurality of components are configured to communicate with one another using a multi-master communications system.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Certain preferred embodiments of the present disclosure will now be described in greater detail, by way of example only and with reference to the following figures, in which:

(2) FIG. 1 shows schematically part of a fire protection system comprising a plurality of fire detectors;

(3) FIG. 2 shows schematically a portable tool communicating with multiple components of the fire protection system;

(4) FIG. 3 shows schematically part of a fire protection system comprising a portable tool and multiple components;

(5) FIG. 4 shows schematically a portable tool communicating with one component of the fire protection system via another component;

(6) FIG. 5 shows schematically a portable tool communicating with multiple components of the fire protection system via one component of the fire protection system; and

(7) FIG. 6 shows schematically detail of a component of the fire protection system.

DETAILED DESCRIPTION

(8) FIG. 1 shows schematically part of a fire protection system 100 in accordance with various embodiments. As shown in FIG. 1, the fire protection system 100 may comprise a fire control panel 12 and a plurality of components 14 connected via wiring 10 to the fire control panel 12.

(9) In the embodiment illustrated in FIG. 1, each of the components 14 is a fire detector, which in this example are illustrated as smoke sensors. However, more generally, the plurality of components may include one or more fire detectors (such as one or more smoke and/or heat sensors), one or more manual call points, one or more fire alarms, one or more fire suppression systems (such as one or more sprinklers, fire barriers, smoke extractors, etc.), and the like.

(10) Thus, each component of the fire protection system may comprise any one of a fire detector, a smoke detector, a heat detector, a manual call point, a fire alarm, a fire suppression component, a sprinkler, a fire barrier, a smoke extractor, and the like.

(11) The plurality of components 14 of the fire protection system 100 may be electrically connected via wiring 10, for example in a loop configuration, with the connecting wiring 10 being connected to (for example, starting and finishing at) the fire control panel 12. The fire protection system 100 may be configured such that each component 14 receives electrical power from the fire control panel 12 via the wiring 10.

(12) The fire protection system 100 may be configured such that the fire control panel 12 can communicate with (and control) each component 14, for example via the wiring 10. This communication may be configured in a master/slave configuration, whereby the master fire control panel 12 can request information from and/or control each slave component 14 of the fire protection system 100.

(13) FIG. 2 shows schematically part of a fire protection system in accordance with various embodiments. As shown in FIG. 2, one or more components 14 of the fire protection system 100 may be installed in a ceiling of a building.

(14) The fire protection system 100 may be configured such that one or more or each component 14 can communicate with a portable device or tool 20 of the fire protection system 100 via a wireless communication protocol. Each component 14 may be configured to communicate wirelessly with the portable tool 20 using any suitable (e.g. short-range) wireless communications protocol, such as for example Wi-Fi, Bluetooth, RFID, and the like.

(15) The portable tool 20 may take any suitable form. For example, the portable tool 20 may be in the form of a “standalone” control device which may optionally be controllable via a mobile communications device 22 such as a mobile phone (cell phone), tablet computer, laptop computer, and the like. It would, however, also be possible for the portable tool 20 to be in the form of a mobile communications device such as a mobile phone (cell phone), tablet computer, laptop computer, and the like.

(16) The communication between the portable tool 20 and the component(s) of the fire protection system may be configured in a master/slave configuration, whereby the master portable tool 20 can request information from and/or control each slave component 14 of the fire protection system 100. That is, the portable tool 20 may be configured to act as a master to each component 14, and each component 14 may be configured to act as a slave to the portable tool 20.

(17) The portable tool 20 may be configured to transmit one or more commands to a component 14. The one or more commands may, for example, request data from the component 14 and/or cause the component to be configured as desired by the operator. The component 14 may receive the command(s) and may be configured to operate in accordance with the command(s), for example by configuring itself accordingly and/or transmitting data to the portable tool 20.

(18) As illustrated in FIG. 2, the portable tool 20 can be employed by an operator, for example during installation of the fire protection system, in order to locally communicate with each component 14. The operator may use the portable tool 20 to obtain component information and/or to configure each component 14.

(19) The component information can comprise, for example, configuration information such as device address and sensitivity profile(s), log information, and the like. The device address, sensitivity profile(s), and the like of each component 14 can be configured by the portable tool 20.

(20) FIG. 3 shows schematically part of a fire protection system in accordance with various embodiments. FIG. 3 shows two components 14a, 14b of the plurality of components 14 of the fire protection system 100, which in the example of FIG. 3 are a fire detector 14a and a manual call point (MCP) 14b.

(21) FIG. 3 also shows the portable tool 20 wirelessly communicating with one component 14a of the plurality of components 14 (as described above). In the example shown in FIG. 3, the portable tool 20 is in the form of a “standalone” control device which may be controlled via a mobile communications device 22 such as a mobile phone (cell phone).

(22) As described above, in accordance with various embodiments, at least one component 14a of the fire protection system 100 comprises communications circuitry configured to communicate with another component 14b of the fire protection system 100. Thus, for example, in the embodiment illustrated in FIG. 3, a first component 14a (being a fire detector) is able to communicate with a second component 14b (being a manual call point (MCP)).

(23) As described above, the communications circuitry provides the component 14a with the ability to communicate directly with the other component 14b. In other words, the communications circuitry facilities component-to-component communications in the fire protection system 100. This in turn improves the flexibility and functionally of the fire protection system 100.

(24) Where, as shown in FIG. 3 (and described above), the fire protection system comprises a portable tool 20, the provision of the communications circuitry can allow the portable tool 20 to communicate (remotely) with the second component 14b of the fire protection system via the first component 14a. For example, when locally communicating with the first component 14a of the fire protection system 100 via (e.g. short-range) wireless communications, the portable tool 20 can communicate with the second component 14b of the fire protection system 100 by instructing the first component 14a to communicate with the second component 14b. The first component 14a can in effect act as a relay between the portable tool 20 and the second component 14b, in order to relay communications between the portable tool 20 and the second component 14b.

(25) This then allows the portable tool 20 to communicate with one or more components 14b of the fire protection system 100 that would otherwise be outside of the range of the portable tool's (e.g. short-range) wireless communications. This can in turn provide a number of advantages.

(26) For example, as illustrated by FIG. 4, this allows an operator to communicate with a component 14b of the fire protection system that would otherwise be difficult or impossible to reach using the portable tool 20, for example where the component 14b is installed in a relatively inaccessible location that is outside of the range of the portable tool's 20 (e.g. short-range) wireless communications, such as within a high ceiling. This can be done by the operator communicating with a relatively more accessible component 14a, such as a manual call point, and the relatively more accessible component 14a relaying communications to the relatively inaccessible component 14b, for example via the wiring 10 of the fire protection system.

(27) As illustrated by FIG. 5, this also allows an operator to communicate with multiple components 14a-14d of the fire protection system 100 without having to physically move to within range of each of those components 14a-14d. For example, as shown in FIG. 5, an operator can use the portable tool 20 to communicate with multiple components 14b-14d via one component 14a (such as a relatively accessible manual call point (MCP)) of the fire protection system 100.

(28) This can increase the operator's efficiency, for example during installation or maintenance of the fire protection system, in particular where components of the fire protection system are physically dispersed, such as being installed in different rooms or on different floors of a building.

(29) In various embodiments, it would be possible for the communications circuitry to be configured to communicate with the other component via wireless communication, such as for example Wi-Fi, Bluetooth, RFID, and the like.

(30) However, in various particular embodiments, the communications circuitry is configured to communicate with the other component via a wired connection. For example, the communications circuitry may be configured to communicate with the other component via the connecting wiring 10.

(31) The component-to-component communication may be configured in a master/slave configuration, whereby a master component 14a can request information from and/or control each slave component 14b-14d of the fire protection system 100. That is, a component 14a may be configured to act as a master to another component 14b-14d, and the other component 14b-14d may be configured to act as a slave to the component 14a.

(32) The communications circuitry of the master component 14a may be configured to transmit one or more commands to the slave component(s) 14b-14d. The one or more commands may, for example, request data from the slave component(s) 14b-14d and/or cause the slave component(s) 14b-14d to be configured as desired by the operator. The slave component(s) 14b-14d may receive the command(s) and may be configured to operate in accordance with the command(s), for example by configuring itself accordingly and/or transmitting requested data back to the master component 14a.

(33) The data may comprise data relating to the status or configuration of the slave component(s) 14b-14d such as device address and sensitivity profile(s), log information, and the like. The device address, sensitivity profile(s), and the like of each slave component(s) 14b-14d can be configured by the portable tool 20 via the master component 14a.

(34) The communications circuitry allows the portable tool 20 to be used to communicate with any one of a plurality of components 14a-14d, via one 14a of the components. The communication between the portable tool 20 and the slave component(s) 14b-14d via the one component 14a may be configured in a master/slave configuration, whereby the master tool 20 can request information from and/or control each slave component 14a-14d of the fire protection system 100. That is, the tool 20 may be configured to act as a master to each component 14a-14d, and each component 14a-14d may be configured to act as a slave to the portable tool 20.

(35) The portable tool 20 may be configured to transmit one or more commands to the slave component(s) 14b-14d via the one component 14a. The one or more commands may, for example, request data from the slave component(s) 14b-14d and/or cause the slave component(s) 14b-14d to be configured as desired by the operator. The slave component(s) 14b-14d may receive the command(s) and may be configured to operate in accordance with the command(s), for example by configuring itself accordingly and/or transmitting requested data back to the portable tool 20 via the one component 14a.

(36) The data may comprise data relating to the status or configuration of the slave component(s) 14b-14d such as device address and sensitivity profile(s), log information, and the like. The device address, sensitivity profile(s), and the like of each slave component(s) 14b-14d can be configured by the portable tool 20 via the master component 14a.

(37) Thus, in various embodiments a first component 14a may be configured to communicate with a second component 14b-14d of the fire protection system 100 in response to one or more commands received (via the wireless communications protocol) from the portable tool 20. The portable tool 20 may be configured to receive, in response to the one or more commands, data from one or more of the second component(s) 14b-14d via the first component 14a. In these embodiments, the fire control panel 12 is not involved in the communication between the portable tool 20 and the first component 14a and/or the second component 14b-14d.

(38) One or more or each of the plurality of components 14 of the fire protection system 100 may be configured in the manner of the invention. In various particular embodiments, there are plural components of the plurality of components 14 of the fire protection system 100 that are each configured in the manner of the invention. Thus, one or more or each component of the plurality of components 14 may comprise communications circuitry configured to communicate with another component of the fire protection system 100.

(39) In these embodiments, one or more or each component of the plurality of components 14 may be able to act as a master to one or more or each other component of the plurality of components 14. Correspondingly, the fire protection system may be configured such that one or more or each component of the plurality of components 14 can act as a slave to one or more or each other component of the plurality of components 14. Thus, the fire protection system 100 may be configured as a multi-master system.

(40) FIG. 6 shows schematically a component 14 of the fire protection system configured in accordance with various embodiments. The component 14 may comprise any one of a fire detector, a smoke detector, a heat detector, a manual call point, a fire alarm, a fire suppression component, a sprinkler, a fire barrier, a smoke extractor, and the like.

(41) As shown in FIG. 6, the component 14 may comprise a master control unit (MCU) 32. This may communicate with a memory 34, which may store (e.g.) configuration information such as device address, sensitivity profile, etc., and log information, and the like.

(42) As also shown in FIG. 6, the (master control unit (MCU) 32 of the) component 14 may be configured to communicate with the fire alarm control panel (FACP) 12 of the fire protection system 100, for example via the loop wiring 10, as described above.

(43) The component 14 may be configured to communicate wirelessly with a portable tool 20. In the example illustrated in FIG. 6, this is done via RFID communication, and so the component 14 comprises RFID communications circuitry in the form of an RFID tag 30. It would be possible, however, for the component 14 to communicate with the portable tool 20 using some other wireless communications protocol (as described above). Thus, the component 14 may comprise communications circuitry configured to communicate wirelessly with a portable tool 20 of the fire protection system 100.

(44) The master control unit (MCU) 32 may communicate with the RFID tag 30 via an internal wired connection, using any suitable protocol such as for example I2C communication.

(45) It will be appreciated that allowing the component 14 to communicate wirelessly with the portable tool 20 (which can optionally be controlled by a mobile application) means that an operator can query device information. It also allows parameter configuration such as device address or sensitivity profiles.

(46) As also shown in FIG. 6, in accordance with various embodiments, the (master control unit (MCU) 32 of the) component may be configured to communicate with another component 14b-14d of the fire protection system 100, as described above. This communication may be via the loop wiring 10 or otherwise (as described above).

(47) This allows the operator to be able to communicate with other devices via the component 14. As described above, this means that the operator need not be near a component in order to be able to interact with it (which may be impractical in installations such as buildings with several floors, or with high ceilings in which the available range may be insufficient).

(48) Various embodiments accordingly allow fire devices to transmit information through the wired loop 10 using a multi-master system which enables communication between any two devices. The protocol can carry information on demand from one device to another. In this way, an operator can use the portable tool 20 via a relatively accessible component 14a such as a manual call point (MCP), in order to obtain information from a device 14b-14d installed in another location.

(49) This can circumvent the range and line of sight limitations of the portable tool 20. This can increase the productivity of an operator, for example when installing and commissioning a large number of devices, as this can be done from the same point without having to move to each location. Other activities such as log querying can also be performed in less time.