NO871097L - ALARM, MONITORING AND LIFE SYSTEM. - Google Patents

Abstract

A combined alarm, security and rescue system comprising a room box (33a-33j, 35a-35j) for one or more breathing masks for rescue purposes in an associated room and a two-way communication arrangement, for use for alarm and security purposes of a number of rooms, for example in high buildings (hotels, hospitals, office complexes, and the like). The room box (33a-33j, 35a-35j) is connected via a microswitch or similar actuating means to a data exchange (10) with data screen (21a) and printer (23). Two-way communication is established from the room box via the microswitch to the data exchange and from the data exchange to alarm producers of light and sound on the room box. The data exchange is adapted to emit by means of its own microprocessor alarms to rooms individually or in groups on one or more floors, as required, via the alarm producers of light and/or sound from associated room boxes, while the microswitch in connection with the room box is adapted to emit by manual or other actuation an equivalent signal to the data exchange for indicating room number, floor, hour, and the like.

Description

The present invention relates to a combined alarm, monitoring and rescue system, comprising a storage device or room box, with one or more smoke masks that are easily accessible to the user in an associated room, in order to prevent smoke poisoning for rescue purposes, and a two-way communication device, for use for alarm and monitoring purposes in a number of rooms with associated room boxes, for example in high-rise buildings (hotels, hospitals, office complexes, etc.).

The term storage device generally means a device that fits into the inventory of a hotel room or similar and for example takes the form of a cabinet (box), a drawer or similar cubicle. Herein, the storage device is generally referred to as a "diamond box".

There are known safety systems for use in the event of a fire, in the event of extreme smoke development, in the event of attempted break-ins and in various other conditions that must be monitored, for example for use in hotels, in hospitals, in office complexes, on board cruise ships, on board offshore installations, etc. ., where there may be a number of people in larger or smaller groups in a number of rooms. Such known systems have used, for example, manually triggered detectors or detectors that are triggered by automatic sensing of movement, smoke generation, heat generation, etc. The detectors can, in turn, trigger light and/or sound alarms locally and/or in more remote locations or they can send another signal to the monitoring center or a signal to trigger a sprinkler system or similar. Such known systems have, however, been plagued with certain shortcomings and have in many cases proven to be insufficient, particularly when it comes to saving human lives under difficult conditions.

Particularly in connection with high-rise buildings and especially in the upper and middle areas of high-rise buildings, but also in other contexts, difficult conditions can arise, for example in a combination of strong smoke, lack of light in the event of a power cut and blocked escape routes. It has been shown, especially in connection with hotel fires, that smoke poisoning in particular has been a significant cause of death. Despite the widespread use of supposedly safe warning and rescue systems, several deaths have occurred quite recently, which could probably have been avoided by the use of better-suited equipment and a better system.

Under special conditions, for example on board offshore installations, it is common for a brochure to be posted in all rooms/cabins about how the safety system works and how the room user or guest should behave when it is relevant to use a smoke mask or other equipment. In addition, each smoke mask has separate instructions for use for the mask. On the inside of the room box that contains such equipment, there is an instruction manual in fluorescent (fluorescent) writing. Under such special conditions, there is an opportunity to keep such a safety system in order, but there is no full guarantee that the equipment is in place and ready for use at any given time. Under certain conditions, there is a risk that the equipment will be stolen, destroyed or otherwise handled in an undesirable manner, so that it may be unavailable in a disaster situation. In all cases, one does not have a complete overview of or control over each individual smoke mask at any given time.

In practice, it is also difficult in connection with an actual rescue operation, in a disaster situation or in the run-up to such a situation, to keep track of and control where each individual user of the room is in the relevant case, i.e. whether the person in question is in the room or is located elsewhere, or whether the various rooms are in use at all. During a rescue operation, there is a need to have the best possible overview in advance, i.e. prior to the initiation of the rescue operation, both in terms of which rooms contain users and/or guests and in terms of the condition of the equipment to be be in the relevant room.

With the present invention, the aim is to create the conditions for a system with which one can obtain an easy overview of and control of the presence of people in the various rooms as well as an overview of and control of disposable equipment, such as a smoke mask, on relevant room. Firstly, the aim is to store smoke masks and other relevant equipment in a room box and by means of remote monitoring from a data center of any opening of the room box, the aim is to ensure that smoke masks and other equipment are intact and ready for use in relevant instances. Secondly, the aim is, in parallel with the aforementioned remote monitoring from a data centre, to create a two-way communication system from and to the data center to and from each individual room via the associated room box. In other words, the aim is to have the room box in each individual room serve as a separate communication link to and from the data centre, so that you can have a constantly open communication line between the data center and the individual room with associated continuous monitoring of the room box. It is clear that the communication system can become rather complicated by simultaneous communication with all rooms via the data centre, but by using simple, coded signals, fast and efficient communication can still be achieved even in large systems that must control a large number of separate room boxes.

The system according to the invention is characterized by the fact that the room box via a micro-switch or similar influencing device is connected to wires or via a cable connection to a data center with a printer and that two-way communication is established from the room box via the micro-switch to the data center or from the data center to the alarm generator(s) for light and sound on the room box, as the data center is designed to use its own micro-processor to issue an alarm to the individual room or to a group of rooms on one or more floors as required, via the alarm transmitter(s) for light and/or or sound from the associated room box, while the micro-switch in connection with the room box is designed to, by manual or other influence, emit a corresponding signal to the data center to indicate the room number, floor, time, etc.

Using the above-mentioned system with two-way communication, it is possible, from a common exchange, to have an open connection simultaneously to and from a number of separate rooms, each with its own room box. Hereby, among other things, a joint notification can be issued to certain, specified rooms or possibly to a large number of rooms, at the same time. As a reaction to the notification or possibly independently of such a notification, for example by manual signal triggering via the micro-switch in the room box in an arbitrary room to the data center, it is possible with automatic instructions in the center of room number, floor, time, etc. different specific warning signals are also emitted which are representative of different conditions in the relevant room. This provides an opportunity for rapid notification to and from the central office, so that the central office can obtain a quick overview of the situation in the entire system and make rapid further dispositions and actions that may be necessary in various current situations.

According to a special, particularly preferred solution, the system includes a room box, which can be equipped with smoke mask(s), flashlight(s), etc. and which are preferably sealed and arranged so that when the room box is opened, via the micro-switch, to emit a corresponding signal to the data center to indicate the room number, floor, time etc.

In this way, as soon as the user of the room has received a notification from the control center and has opened the room box, they can immediately receive feedback that the notification has been received and that the user is in the process of putting on a smoke mask etc.

Similarly, it can be ensured that if the user of the room opens the room box untimely, for example out of curiosity, this is accordingly notified to the central office, so that the operator can contact the user in question by telephone or during a visit to clarify the situation. In this way, you can possibly also make sure during a visit that the room box is in a fully operational condition at all times, i.e. reset to the initial position in a sealed condition.

Optionally, the micro-switch can be used for other notification functions in addition to the notification of the opening of the room box, such as notification of a break-in, notification of heat or smoke, etc., so that the control center can have a full overview and permanent connection to each room at all times with continuous monitoring via an open two-way communication line.

It is preferred that the system includes a smoke and/or heat-sensing or burglary-sensing device which is connected to the room box for transmitting a warning signal about smoke or heat development and/or burglary etc. to the data center and simultaneously issuing an alarm via an alarm transmitter for light and/or sound from the room box.

In the event that a large number of notifications or signal transmissions occur at the same time, you have the option of recording this with the time, floor, room number, type of notification etc. in turn via the control panel's memory on the computer screen, by printer or by additional signaling (sound or light) in the central office.

Further features of the invention will be apparent from the following description with reference to the accompanying drawings, in which: Fig. 1 shows in a block diagram a system according to the invention. Fig. 2 schematically shows an alarm box for the alarm signal that emanates from the data center to the various individual rooms. Fig. 3 schematically shows an alarm box for the alarm signal that enters from the various individual rooms to the data center. Fig. 4 shows a floor box to which the different rooms on each floor of a building are connected.

Fig. 5 shows a room box.

In fig. 1, in connection with a data center 10, as shown with dashed lines, there is shown a connection point 10a to 220V mains voltage with wire connections 11 to a battery charger 12 (220V/12V) with wire connections 13 on to a rechargeable nickel-cadmium battery 14. Low voltage ( 12V), direct current wire connections 15 from the battery 14, are via two main fuses 16 connected to wire connections 17 to a converter 18. Alternating current (220V) wire connections 19 from the converter 18 supply power to a PC terminal 21. Via wire connections 22, the PC terminal 21 connected to a printer 23.

A first multi-cable 24 from the fuses 16 runs to an alarm box 25 for the outgoing alarm signal (audio or light signal), i.e. signals emanating from the data center 10 to external rooms. A second multi-cable 26 from the terminal 21 runs to another alarm box 27 for incoming alarm signals, i.e. signals entering the data center from external rooms. The multi cables 24 and 26 are connected to each other via a third multi cable 28 and the alarm boxes 25,27. From each alarm box 25 and 27, a number of multi-cables 29a, 29b, 29c and 30a, 30b, 30c respectively run to a respective floor box 31a, 31b (etc.) in a corresponding number of floors. In the design example shown, only a number of three cables for three floors are shown, while in practice a larger number of floors and a correspondingly larger number of cables can be arranged. From floor box 31a, separate coaxial cables 32a-32j run to respective room boxes 33a-33j and correspondingly on each subsequent floor, as illustrated, where, for example, separate coaxial cables 34a-34j run from floor box 31b to respective room boxes 35a-35j.

It is essential that the entire system, including the communication device and the individual room boxes with associated signal generator and signal receiver, is connected to a common mains power system which can be switched to a separate battery system. In the communication system, the aim is to incorporate the following: - two-way communication line between the data center and the individual room, - automatic signaling to the data center from various manually actuable signal generators built into the room box, access door, etc. for notification of the opening of the room door lid, cabin door, movement in the room (cabin), warning of smoke generation, heat generation, etc. - triggering of an alarm in the room (cabin) from internal signaling or from external signaling (for example from central) and simultaneous registration centrally and possibly triggering of an alarm or instruction locally from external signaling.

The connection between the individual rooms and the center can be made via coaxial cables (multi-cables, broadband cables, fiber cables or similar). The system can optionally be operational wirelessly with a transmitter and a receiver centrally as well as externally and then connected to their own battery/power systems.

In fig. 2 shows the alarm box 27 for the incoming alarm signal, i.e. the alarm signal that goes from the individual room to the data centre. A microprocessor 36 for alarm control is shown, with associated connection strip 37 for connecting cables, here shown by the cable 30a. At 38 are shown connection points for the cable 26 and at 39 are shown connection points for the cable 28 in direct connection with the microprocessor 36. At 40 is shown the connection of the cable 28 to a 5V voltage regulator 41, with corresponding connection points 42 in direct connection with the microprocessor 36.

In fig. 3 shows the alarm box 25 for the outgoing alarm signal, i.e. the alarm signal that goes from the control panel to the individual room. A microprocessor 44 is shown with a series of relays 45a, 45b etc. for each floor. By placing several printed circuit boards on top of each other, several alarm signals can be emitted as required. Two cables 29a and 29b are shown (one for each floor) which are connected to relays 45a and 45b respectively. A fuse 46a or 46b is connected to each relay, etc. Connection points for cable 24 and certain wires in cable 26 are shown at 47 and connection points for other wires in cable 26 are shown at 48.

In fig. 4, a floor box 31a is shown. Such a box 31a or 31b, etc., is mounted on each floor and forms the connection between each room and the exchange. The cables 32a respectively 32b-32j which come from the respective room box 33a respectively 33b-33j run into the floor box 31a respectively the floor box 31b, etc., separately, to a common alarm connection strip 51 respectively to common direct current (+/-) connection strips 52 and 53. From the connection strip 51, the multi-cable 30a runs to the alarm box 27, while from the connection strips 52,53 wires run from the multi-cable 29a to the alarm box 25.

If there are few rooms on each floor, the cables 30a, 30b, 30c etc. from the alarm box 27 can be combined in a common cable to two or more floor boxes 31a, 31b, etc. In contrast, the cables 29a, 29b etc. run directly from the alarm box 25 and each directly to their respective floor boxes 31a, 31b, etc.

Each room box 33a-33j, 35a-35j, etc. is similar to that shown for the room box 33a in fig. 5 equipped with a lid 55 of transparent material (plastic or similar). The box can, for example, be sized to accommodate three smoke masks and three flashlights (not shown). In connection with the lid, a microswitch 56 is mounted inside the box. When the lid is opened, this is registered via the microswitch 56 and a signal is sent via the associated cable 32a to the floor box 31a and further via the alarm box 27 to the PC terminal 21. On top of box, a warning light 57 and a sounder 58 are placed. A warning signal from the PC terminal 21 is transmitted via the alarm box 25, the floor box 31a and the cable 32a to the room box's 33a (33b, etc.) warning light or sounder, controlled from the PC terminal.

With the help of the regulator 41 and the microprocessor 36 in the alarm box 27, a few thousand room boxes 33a-33j, 35a-35j, etc. can be controlled simultaneously. With the help of the microprocessor 36, all the cables coming from the aforementioned room boxes can be checked. As soon as the lid of a room box is opened (out of curiosity or for another reason), this is notified to the PC center as a result of the influence of the microswitch 56 in the respective room box. This will be registered in the PC centre, both in the memory and on the computer screen and via printer, where an impact of a room box lid is registered by specifying the room number, floor and time. The PC central's operator can then contact the relevant room by telephone via a separate telephone or via a direct speaker connected to the room box via the existing communication system or in another way (for example during a visit) to ensure that the system is reset and/or to check that the system is in proper operational condition.

Without it being shown in more detail here, the room box can also be used

additional warning devices, for example smoke alarms, heat alarms, burglar alarms, etc., can be connected to the aforementioned notification of the opening of the room box lid. As soon as such a notification device is triggered, the PC center can be informed accordingly via the same

communication system. The PC central's operator can then, similarly as mentioned above, check the conditions via the communication system or in another way.

In response to a locally issued notification from one of the rooms or from another notification device outside the rooms, a notification can be sent centrally from the PC center to specific rooms or to rows or floors of rooms about fire or other danger, controlled directly from the central.

As a further reaction from the individual rooms, feedback of a signal that the centrally issued notification has been received can be sent locally to the central. This can be done, for example, by opening the associated room box and thereby influencing the microswitch 56. Alternatively, another microswitch can be used instead of the room box's microswitch. In the PC center you can generally have a running overview of which (hotel) rooms have guests at any time and can quickly compare this with local feedback from the respective rooms that a centrally issued notification has been received.

According to the invention, it is possible, with a particularly simple and easy-to-understand communication system, to monitor, notify and give feedback in a particularly fast and accurate way, from and to the central office to and from the individual room. By combining the communication system with a normally sealed room box for the individual room, where the room box contains equipment such as smoke masks, flashlights, etc. that may be used in conditions with strong smoke development, with fire access or the like, you have the opportunity to obtain an effective notification system with automatic feedback when the room box lid is opened. As soon as the lid 55 on the room box (33a) is opened, the microswitch 56 initiates a signal to the floor box (31a) which sends a signal further down to the alarm box 27 and the microprocessor 36 in this registers that said lid has been opened. The microprocessor 3 6 then sends a coded signal on to the PC terminal 21. The signal is registered and displayed on the screen 21a indicating the room number, floor, time, etc. The alarm is stored in the memory 21b and printed on the printer 23. In the case of the central registration of the individual notifications issued from the central via the desk 21c and the individual feedback from the respective rooms and the times for these as well as room number, floor, etc., possibly in combination with central overview of the number of people (guests) in the individual room and on the individual floor, you have the possibility of efficient and quick coordination of any rescue operation via computer screen, printer and pre-programmed follow-up operations. This is in addition to the feedback with the indication that the person or persons in the room in question giving feedback have prepared themselves with a smoke mask, etc.

A particular advantage is that the system according to the invention can be connected by relatively simple means, for example to an existing coaxial cable network for television in connection with hotels or to another coaxial cable network which is used for other purposes in connection with hospitals or similar institutions.

Claims (3)

1. Combined alarm, monitoring and rescue system, comprising a storage device or room box (33a-33j,35a-35j), with one or more smoke masks that are easily accessible to the user in an associated room, in order to prevent smoke poisoning for rescue purposes , and a two-way communication device, for use for alarm and monitoring purposes in a number of rooms with associated room boxes, for example as in high-rise buildings (hotels, hospitals, office complexes, etc.), characterized by that the room box (33a-33j,35a-35j) is connected via a microswitch (56) or similar influencing device to wires or via a cable connection to a data center (21) with a printer (23), and that two-way communication has been established from the room box via the micro-switch (56) to the data center (21) respectively from the data center to alarm transmitter(s) (57,58) for light and sound on the room box, as the data center is designed to issue an alarm to the individual room or to a group of rooms on one or more floors as needed, using its own micro-processor, via the alarm transmitter(s) (57,58) for light and/or or sound from the associated room box, while the micro-switch (56) in connection with the room box is arranged to, by manual or other influence, emit a corresponding signal to the data center (10) for indication of room number, floor, time, etc. 2. System in accordance with claim 1, characterized by that each room box (33a-33j, 35a-35j), which may be equipped with smoke mask(s), flashlight(s), etc., is sealed and arranged so that when the room box is opened, via the microswitch (56), to emit corresponding signal to the data center (10). 3. System in accordance with claim 1 or 2, characterized by that the room box is connected to a battery that can supply the system with a separate power supply, for example 3 6 hours from a power cut, as the system's battery is connected to mains power via a transformer/regulator.