FI73095C - Signal station for a fire alarm system. - Google Patents

Description

1 73095

This invention relates generally to a signal station for a fire alarm system which responds to a fire signal from means of detecting a fire event, such as fire detection means, and activates alarm means to give an alarm, and more particularly to a signal station capable of issuing and the actions to be taken when a fire breaks out, etc. · when these messages are in the form of speech generated by speech synthesis means.

Examination of the facts about fires in buildings, hotels, etc. reveals that most fires and tragedies caused by fire could have been prevented if the fire station had been contacted quickly when the fire started, or if people were directed more appropriately to a safe place. The main reason for causing such serious problems is that the doormen of the buildings or the hotel staff have not taken the appropriate measures, even though the fire alarm system has worked properly.

Generally, a conventional fire alarm system includes a signal station coupled to fire alarm means such as fire detectors, pushbuttons, etc. for receiving a fire signal therefrom, alarm means including a clock, lamp, etc. and operating means for operating the fire alarm system and associated means as needed. This conventional signal station generates an alarm by making the clock ring and turning on the lamp when it receives a fire signal, but it does not provide instructions on the actions to be taken during a fire.

2 73095 such as operating procedures for operating means. These procedures are usually described in the instruction manual or indicated on the panel. If the doormen or staff are inexperienced in using the signal station, or if they are confused, they will not be able to act quickly and properly, or will not be able to take the necessary action, or they will be using the signal station incorrectly. From this point it can be concluded that it is very important to teach and practice the measures to be taken in the event of a fire and to practice the use of the equipment related to the fire alarm system. Today, however, there are no ways to easily and effectively teach and practice the measures needed during a fire. In particular, there is very little opportunity to gain experience in the use of equipment and installations related to the fire alarm system, as they are not used on a daily basis. In addition, it is cumbersome and therefore irrelevant to read the instruction manual to remember the actions to be taken during a fire.

It is a first object of the present invention to provide a signal station for a fire alarm system which, upon receiving a fire signal, is able to output messages of necessary functions pre-stored in storage means, in the form of speech, to instruct doormen or staff to act quickly and properly.

Another object of the present invention is to provide a signal station for a fire alarm system which, upon request, is able to output messages from a fire alarm system and associated equipment manual as needed and messages about necessary functions during a fire, in speech, to teach and practice doormen or personnel.

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A third object of the present invention is to provide a signal station for a fire alarm system equipped with notification devices capable of giving guidance messages in emergency situations.

According to the invention, this is provided in that the s.ig signal station comprises: storage means for storing messages concerning the measures to be taken during a fire, for storing messages concerning the operating and processing methods of the fire alarm system and associated equipment, and for storing messages training to be provided during a fire; speech synthesizing means for synthesizing speech signals for output messages of the storage means; speech output means for outputting speech signals as speech; manual input means for assigning any desired message from the messages stored in the storage means, and for generating a signal requiring the output of the message in a normal time to request the output of the assigned message; and process means for receiving and processing the fire signal and the message output signal to select for the fire signal messages regarding actions to be taken during the fire, and the message required for the message output signal from the stored media and controlling speech synthesizing means to convert the message into speech.

Preferred embodiments of the invention appear from the appended subclaims.

The invention will now be described in more detail with reference to the accompanying drawings.

Figure 1 shows a first embodiment of a signal station for a fire alarm system according to the present invention.

Figure 2 is a block diagram of a fire alarm system incorporating a signal station according to the present invention and associated equipment.

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Figure 3 is a block diagram of the process means used in the embodiment, showing their input and output conditions.

Fig. 4 is a table illustrating storage areas and output addresses of messages stored in the storage media used in the embodiment.

Figure 5 is a block diagram of one form of speech synthesis devices used in the embodiment.

Fig. 6 is a block diagram showing one form of the speech synthesizing portion of the speech synthesizing means illustrated in Fig. 5.

Figure 7 is a block diagram of another form of speech synthesis section.

Fig. 8 is a flowchart showing the main routine of the process means.

Fig. 9 is a flowchart showing in detail the data process operation in the main routine.

Fig. 10 is a flowchart detailing speech control operation in the main routine.

Fig. 11 is a flowchart detailing the operation for the operations to be performed in a speech control system during a fire.

Fig. 12 is a flow chart detailing the fire notification operation for the actions to be taken in the event of a fire.

Fig. 13 is a flowchart detailing the operation during exercise.

Fig. 14 is a block diagram of another embodiment of a signal station for a fire alarm system according to the present invention.

Figure 1 is a block diagram of a first preferred embodiment of the present invention. The signaling station of the fire alarm system includes process means 11 for processing the input signal for controlling various devices and instructing the necessary operations thereon, storage means 16 for storing messages on measures to be taken against fire, manual 73095 input means 15 to sound the messages output from the recording means 16, speech output means 18 for outputting a speech signal and display means 17 indicating the required facts. The signal station 10 further comprises receiving means 12, alarm means 13 and operating means 14.

Figure 2 illustrates one form of fire alarm system to which a signal station according to the present invention may be conveniently connected. This fire alarm system includes a signal station 10, a signal line 1 connected to this signal station, wired to different parts of the building, connection stations 2 each equipped with appropriate fire blocks and connected to signal line 1, fire detectors 3a and manually operated pushbuttons for fire connection, all connected to 2 together with the identification signal switching means 4 and the alarm clocks 5 and the fire door tripping means 6, which are also connected to each connection station 2. This fire alarm system further comprises, as ancillary devices, a fire post 7, a sprinkler 8, etc. operatively connected thereto. The notification devices 9 can also be connected to the signal station 10 as required. It is not always necessary to equip the system with all these devices and facilities, but other devices and facilities can be connected to it if necessary.

For example, as illustrated in Figure 3, the process means 11 includes a central processing unit (CPU) 11a, a non-volatile memory (ROM) 11b, the contents of which are not erased or erased, a pick-up memory (RAM) 11c into which 6 73095 can be written and an input / output port (I / O-port) lld and common line (bus) lie for connections between them. The ROM 11b stores the programs on the CPU 11a and this runs various process functions according to the programs. RAM 11c is a temporary memory used to drive the CPU 11a.

The I / O port lld is used to connect various input / output devices to the process means 11 and in the illustrated embodiment the I / O port lld connects the receiving means 12, the manual operation input means 15, the alarm means 13, the operating means 14, the display means 17 and the speech synthesizing means 20 to the relevant process means 11. through. Other devices or facilities such as a printer can also be connected.

As shown in Fig. 3, the receiving means 12 includes a receiving circuit 12a connected to the signal line 1 and an interface 12b for connecting the output signal of the receiving circuit to the input of the process means 11. The receiving means 12 receive a fire signal from the fire detectors 3a, etc. as an indication of a fire occurring, and further receive a block identification signal and an identification signal from the combining station 2 and the identification signal combining means 4, and the interference signal and normal signal that the receiving means receives all these signals. In a fire alarm system of the simplest construction, it is sufficient for the receiving means 12 to receive only a fire alarm signal. The receiving means 12 may further serve to transmit the signal to the combining station 2, the fire detectors 3a, etc. Depending on the conditions, the receiving circuit 12a may be omitted. In this case, the terminal 12b can be directly connected to the signal line 1.

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The manual input means 15 includes, for example, as shown in Fig. 3, a switch group 15a and an interface 15b, and generates a signal requiring a message output to request a message output stored in the storage means 16, as will be explained in more detail below. These messages can be selected and the selection is carried out with a code formed, for example, by an on-off combination of the switch group 15a. Using the manual input means 15, messages indicating the necessary actions to be taken during a fire or messages from the instruction manual of the fire alarm system and associated equipment and fire drills can also be performed during normal time. Alternatively, the manual input means 15 may be configured such that the switches 15a are pre-connected to correspond to the relevant codes, so that the codes can be selected using a selector switch or by pressing pushbuttons corresponding to the relevant codes. Furthermore, the manual input means 15 may alternatively be formed as a keypad. In the latter case, the input of false fire data for training can be easily implemented.

The alarm means 13 include sound generating means such as a clock and a lamp and are adapted to be operated by a signal from the process means 11 to which they are connected via an interface (not shown).

The operating means 14 includes a circuit part, switches for issuing commands to the circuit part, a telephone, etc. and are adapted to be used manually or automatically to stop the sound of the alarm means 14, to make calls to required locations and to initiate appropriate devices such as sprinklers, etc. In the illustrated embodiment, these operating means 8 73095 are further adapted to supply to the process means 11 an operation confirmation signal (acknowledgment signal) to confirm that the required operations are reliably performed depending on the operation of the operation means 14. However, it is not always necessary for the operation means 14 to produce an operation confirmation signal. The operating means 14 may be formed independently of the process means 11 and without connection to the latter.

The display means 17 comprises a combination of a signboard (numbers and / or letters) and an indication lamp. The simple display is formed of 7-segment light emitting diodes, liquid crystal drive to indicate the block name where the fire occurs, the operations to be performed, etc. in letters or characters on the signal station panel. Alternatively, a cathode ray tube (CRT) display may be used as the display means 17. In this case, the messages stored in the storage means 16 can be addressed simultaneously or independently of the speech synthesis means 20. Depending on the case, these display means 17 can be omitted from the fire alarm system.

The storage means 16 is formed of one or more non-volatile non-volatile memories (ROMs) of the random access type and storing messages in the event of a fire, a fire alarm system instruction manual, fire fighting training instructions and, if necessary, messages to control the notification. The storage means 16 may further include RAM as needed. Although the storage means 16 are connected to the speech synthesis means 20 in the illustrated embodiment, the means 16 may alternatively be located in the process means 11.

The storage format of the messages in the storage means 16 varies depending on the type of speech synthesis and / or the number of messages. For example, in the case where speech is synthesized in speech synthesis section 22 as explained in more detail below with reference to Fig. 5, the messages are sequentially stored in the form of voice parameters and an address table is formed to indicate an output address for each message group or word group.

Figure 4 shows an example of an address table in which, for example, the general phrase "fire has started at ..." is stored in area a starting from address 100, block names such as "operating room", "department store", "warehouse", "office", etc. is respectively stored in the regions a ^ ... ag from the starting addresses 200-900, respectively. Messages stored in bQ, b- ^ and b ^ ° n, respectively, of the measures to be taken when a fire occurs. Similarly, messages for fire training are stored in areas cq and and data for control notification is stored in areas d and d ,, d. The source addresses shown in Figure 4 are given for ease of explanation, but in reality they are determined by considering the lengths of the messages. Alternatively, the address table may be formed on the ROM 11 and not on the storage media 16.

The speech synthesizing means 20 include, for example, as illustrated in Figure 5, an interface 21 connected to a common line 19 1/0 from the port 11d, a speech synthesizing section 22 for speech synthesis, an audio filter 2 3 for the speech signal and an amplifier 24. The speech synthesizing means 20 is connected to the storage means 16, the speech output means 18 and the process means 11 so as to read messages from the storage means 16 depending on the instructions of the process means 11 and synthesize speech signals for the messages to output them from the speech output means 18.

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For example, as shown in Figure 6, the speech synthesizing section 22 includes a speech synthesizer and 22a formed in the single chip LSI, and a controller 22f for controlling the speech synthesis. The synthesizer 22a includes an audio source 22b, an interpolation circuit 22c, a digital filter 22d, and a digital-to-analog (D / Λ) converter 22e. In the speech synthesizing section, the controller 22f reads the speech parameters forming the message from the addresses in question according to the instruction of the process means 11, the parameters are sequentially input to the speech synthesizer 22a and the speech signal is synthesized based on the pulse input from the audio source 22b. This speech signal is fed to the speech output means 18 via an audio filter 23 and an amplifier 24. The controller 22f outputs a busy signal during these operations. Alternatively, this operation of the controller 22f may be performed by the process means 11. In this case, the controller 22f may be omitted. Further, the controller 22f may alternatively be positioned integrally with the speech synthesizer 22a and, if desired, be further integrated with the storage means 16.

The speech output means 18 includes a speaker 18a located at the signal station and speakers 18b and 18c located at other locations to output the speech signal as speech. These speakers are connected according to the content of the messages to be connected. The speakers can, of course, be switched on by manual operation. Depending on the case, the speakers 18b and 18c may be omitted. In addition to the loudspeaker or loudspeakers, the announcement device may be connected to the speech synthesizing means 20 by similar switching means.

Figure 7 illustrates another form of speech synthesis section 22 that includes a microprocessor 22i, ROM 22g, RAM 22h, and D / A converter 22e. This synthesizing section 22 stores phonemic data from the respective phonons, 73095 11 compiled by PCM recording of natural speech and an editing and synthesizing program in ROM 22g. On the other side of the messages are stored in the character information storage means 16. The microprocessor 22i reads the message from the storage means 16 and corresponding phonemic data from ROM 22g according to the processing means 11 and edits the phonemic data to the editing and synthesizing program for synthesizing a speech signal accordingly. RAM 22h is a memory that is temporarily used by microprocessor 22i during these operations. In the case illustrated in Fig. 7, the operation of the microprocessor 22i may be provided to the process means 11, and the storage means 16 and the ROM 22g may be formed integrated.

The speech synthesis method is not limited to those described above, and other speech synthesis methods can also be used in the present invention. For example, the messages may be PCM-stored, reduced to suitable word or phrase groups for storage on storage media and readable by process media 11 or a special purpose microprocessor for speech editing and synthesis.

The following describes the operation of a signal station for fire alarm systems according to the present invention.

Fig. 8 is a flowchart of a main routine to be run on signal station process means 11 in the illustrated embodiment. To initiate fire signal monitoring after the fire alarm system is installed, process means is initiated at step 30 to clear memories and registers in preparation for running various process functions. The main routine rotates at a constant speed.

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The first operation is to check the line signal 31, whether the signal line 1 (Fig. 2) is operating normally or is not being checked via the receiving means 12. In the next signal line data input operation 32, a signal such as a fire signal and / or an interference signal when such a signal is input from the line 1, or an operation confirmation signal when such a signal is input by the operating means 14 is stored in buffer means, e.g., in a predetermined area in RAM 11c. (not shown), etc. In the manual data input operation 33, the signal requiring message output is likewise stored in predetermined buffer means when such a signal is input from the manual input means 15.

The data processing operation 34 implements the processing of various input data and is described in detail in Fig. 9. First, it is performed to determine 40 whether the input data represents a fire signal. If the answer is yes, the flag representing the fire is set in the flag setting means, such as in a predetermined area of RAM 11c, the block name and identification signal stored in the flag flip flop (not shown), etc. and the buffer means are decoded, changed to my block and identification number and stored in RAM llcrhen (41 and 42 in Fig. 9). The block name and identification number thus stored can be further converted into the output address data of the corresponding block name and identification number speech parameters stored in the storage means 16.

Thus, in step 45, it is determined whether there is a disturbance signal representing a disturbance such as a signal line break, a disturbance in the power supply of the connecting means, and the disconnection of the fire detectors. If the result of the determination is yes, the interference detection flag 73095 13 is set in the flag setting means in the same manner as in step 40, and the interference block name is decoded and stored in RAM 11c (as shown in step 46 in Fig. 9). On the other hand, if the determination result is no, a further steps to implement the functions described above.

At step 47, it is determined whether there is a normal signal representing that the relevant facilities are not in the operating modes, a patrol gain signal for patrol investigation, an operation gain signal, and so on.

If the answer is yes, the flags corresponding to the respective normal signals are set in the flag setting devices and the contents of the signals are decoded and stored in RAM 11c (as shown at 48 in Fig. 9).

If, in step 40, the determination in response to whether the input data signal is a fire signal is no, a determination is made in step 43 whether there is an input signal such as a signal requiring message output, etc. from the manual input means 15. If the determination is yes, a manual input flag is set in the flag setting means and the contents of the input signal are decoded and stored in RAM 11c. Although this step is simply shown in Figure 9 as only one operation 44, this step is performed according to the content of the input, i. the flags are set in response to the flag setting means for the relevant output required messages such as a message for the instruction manual, a message for training the operation control data, etc. When these operations are completed, the program returns to the first operation in the final position of this data process routine. On the other hand, if the determination at 43 is no, the program branches to decision 45 to determine whether there is a trouble signal.

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After the data processing operation 34, the control signal processing 35 is performed according to the main routine. At this stage, the relevant flagging means are checked and a signal is activated to the alarm means1 Le 13 and a control signal is applied to the facilities in question, such as the fire hydrant 7, the sprinkler 8, etc.

The display operation reads the contents of the input signal, e.g. fire signal, interference signal, etc. from the RAM 11c and indicates it in the form of letters and / or characters by the display means 17. In case the cathode ray tube display is connected, the same message is also indicated by the speech synthesizing means 20 synthesized .

In the speech control operation 37, operation control for synthesizing speech for the required message is implemented by the speech synthesizing means 20. This operation is described in detail in Fig. 10. First, at 50, it is determined whether the output of the required message is bypassed. This determination is made by checking whether the fire indication flag and the manual entry flag are set by the functions shown in Figs. 41, 41 and 44. In particular, when these flags are in the return positions, namely when they have never been set or when they have been returned after the completion of operation 52 of the measures to be taken during a fire (hereinafter referred to as "fire operations"), as explained in more detail below, the answer is yes and the program branches to bypass the next speech control operation and the process means 11 drive the next operation of the main routine. On the other hand, when one of the flags is in a set position, the answer to the determination is no and the succeeding voice control operation is carried out. This determination in step 50 may be omitted.

15 73095 The determination in step 51 is made to determine if the messages to be output are fire data, such as data on actions to be taken in the event of a fire, etc. If the answer is yes, fire action is initiated and if the answer is no, the program branches to the next determination. Decision 51 determines whether the messages to be issued are for instruction manual and / or operation instruction messages. If the answer is yes, an action (as described in paragraph 54) is taken to explain the instruction manual for the fire alarm system and associated facilities (in the absence of such facilities, no explanation is required, as explained in more detail below) and an action during the exercise.

If the answer is no, the program branches to the next configuration. In solution 56, it is determined whether the messages to be output are a guidance message, and if the answer is yes, the guidance notification function 57 is performed, while if the answer is no, the program branches to the second step of the main routine.

Among the determinations 51, 53 and 56, the determination of the fire data 51 is privileged, so that when a fire signal is received during the processing of other messages, such as instruction manual messages, etc., the fire operation 52 is performed through the determination of 51. These determinations 51, 53 and 56 are made by checking the states of the flags set in the data processing step 34, as in the case of the determination 50.

In the fire operation 52, as shown in Fig. 11, a determination 60 is first performed as to whether the fire event has already been reported. If the answer is no, fire information is performed. If the answer is yes, the program proceeds to the next determination 62. This determination in step 60 is made by checking the fire informative flag set by the flag setting means 73095 16 after completing the general phase output operation 77, as explained in more detail below. The determinations in steps 70, 74 and 76 as to whether the block name of the fire has been read, whether a common phrase has been expressed and whether the block name has been expressed are made in the same manner.

In the fire information 61, as shown in Fig. 12, a determination is made at 70 whether the block name of the fire has already been read. If the answer is no, the block name is read from the fire data stored in RAM 11c, and the output addresses of the speech parameters corresponding to the block names stored in the storage means 16 are calculated from the read block name. This calculation is performed by referring to an address table formed on the storage means 16 or the ROM 11b.

Then, at step 73, it is determined whether the speech synthesizing means 20 are ready. This is done by checking whether the busy signal has been input from the speech synthesizing section 22 via the interface 5, as shown in Figure 5. If the answer is no (busy), the program branches to the second stage of the main routine, skipping the next speech synthesizing operation. The process means 11 repeat the running of the main routine until the answer is yes (ready). If the answer is yes or yes after repeating the main routine, a determination is made in step 74 as to whether the general phrase has already been expressed.

If the answer is no, the output address of the general phrase "fire has started at ..." read from the storage media 16, e.g., 100 is passed to a speech synthesis section 22 and an output signal is input thereto to synthesize a speech signal for audio transmission of the common phrase (as indicated at 75).

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If a generic phrase is already expressed, it is determined in step 76 whether the block name is expressed. If the answer is no, the source address to be read from the storage media 16, e.g. φ £. 200 for the "operating room", is passed to a speech synthesizing section 22, and an output signal is input to synthesize a speech signal for expressing a block name (as shown in step 75). If the block name has already been expressed, the process means proceed to the next step without performing the latter operation.

Then, at step 62, a determination is made as to whether the main and local sounds have stopped, as shown in Fig. 11. The main sound is the clock of the alarm means 13 located at the signal station and the local sounds are alarm bells placed in the fire blocks in question. If the answer is no, the speech generated by the speech synthesizing means 22 is instructed to cut off the main and local sounds using the same procedure as in the fire information point 61.

This command may be, for example, a message such as "turn the main sound stop switch and the local sound stop switch to the stop position".

If the determination in step 62 is yes, a determination is made in step 64 as to whether the spot has been confirmed. The latter determination is performed by checking the predetermined flag of the flag setting means. When the user has set the position-confirming switch 14 on the signal station to the on position, the predetermined flag is in the 1 position. If the answer is no, no location confirmation command 65 is executed in the same manner. This command could be, for example, a message like "dial a number ... or run to a location to confirm. After confirming, press the confirmation switch".

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If the answer in step 64 is yes / still to be determined / if the operation after position confirmation has already been performed in step 66. This determination is performed by checking the position of the corresponding flag of the flag setting means / in position 1 with the operation confirmation signal from the operating means 14 indicating that the sound stop switch is predetermined position. If the answer is no, the operation command 67 after the location confirmation is executed in the same manner as described above. This command (instruction) may include, for example, the message "If there is a fire, contact the fire brigade and guide people to a safe place. If there is no fire, use the reset switch and return the mute switch to a predetermined position."

The fire operation described above is carried out in such a way that whether the user has performed the required operations or taken the necessary measures is determined by process means 11 and the necessary message or messages selected from the messages concerning the measures to be taken in the event of fire are given out in speech. according to the result of this determination. In this activity, the user can lead the necessary functions and take the necessary actions. However, it is possible to use a system in which the configuration is not performed and all messages are repeated sequentially. In this case, it is sufficient to derive only the output addresses of the messages to be output to the speech synthesis means 20, so that the program of the process means 11 can be simplified and its load reduced.

Action 54 for the instruction manual is intended to explain the procedure for handling the fire alarm system and associated equipment and facilities. With respect to related devices and facilities, only those devices and facilities that require manual operation are described. The explanation includes information and messages on the status of the fire alarm system and the actions to be taken during normal time, in the event of a power failure and during a fire. This explanation is the output of the instruction manual, requiring a signal from the manual input means 15.

The operation 55 for the exercise is carried out by following the operation of the instruction manual in the described embodiment, but it can also be carried out independently. In this operation, as shown in Fig. 13, at step 80, a determination is first made as to whether the exercise start message is over. If the answer is no, a message 81 is displayed about the start of the exercise, for example "Now the exercise activity starts. A fire alarm is given so that you conduct the actions according to the instructions". A fire alarm 82 is then given. On the other hand, if the answer in step 80 is yes, the program branches off, skipping the latter operation. The fire routine 52 is then called, which allows the detected messages to be taken during the fire. A determination is then made in step 83 as to whether the fire-fighting measures have been carried out. If the answer is yes, a message such as "Now the exercise is over" (as shown in paragraph 84) is displayed to end the activity.

In the guidance notification function 57, a notification is given in the form of a speech signal about facilities such as the building's emergency equipment, emergency system, precautions during a fire, etc. The notification can be given whenever desired except during a fire or exercise. For example, in a hotel, etc., messages can be announced at the request of residents. Once a message has been stored in the storage means 16 to guide people to a safe place, a guidance announcement can be made during a fire as well as during training.

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Upon completion of the voice control 37, the process means 11 resets (resets) the flag associated with the voice control and set by the flag setting means after the command to indicate the last message in the fire operation 52, the operation operation 55 and the guidance notification operation 57.

After the voice control is completed, the main routine and the process means 11 return to the signal line check 31. However, if the devices and facilities such as the automatic fire tester, the indication tester, the notification means, etc. are connected, the main routine returns to the signal line check 31 after these devices and the facility management functions have been completed.

When the printer is connected, not only the fire data but also the times when the necessary actions and measures have been taken are written so that it is easy to find out if these actions and actions have been performed correctly. To enter times, the clock must be connected.

The speakers 18a, 18b, 18c of the speech output means 18 are connected so that all the speakers 18a, 18b and 18c or at least the speaker 18a can be connected in the case of a message, for example a fire signal, and only the selected speakers or manual speakers can be connected in other cases. 11 guided.

Figure 14 shows another embodiment of a signal station for a fire alarm system according to the present invention. In this embodiment, the receiving means 12, the alarm means 13 and the operating means 14 are formed separately from the process means 11.

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The receiving means 12 are formed of wired logic, such as relays, etc., as in a conventional fire alarm system, and the alarm means 13 are operated by wired logic. The process means 11 are connected to the receiving means 12 via a connection (not shown) or include a connection for connection to the receiving means 12.

The signal station of the present invention is suitable to be used when required to provide additional functions to the output in the form of speech, messages of actions to be taken during a fire, etc., to a conventional signal station of a fire alarm system.

The process means controls the synthesis of speech in substantially the same way as in the first embodiment, upon receiving the fire signal. However, in this embodiment, the messages are simply repeated because the operating means 14 are not connected to the process means 11. Of course, the operating means 14 may be connected to the process means 11 as in the first embodiment to select appropriate messages as needed to determine if the required operations have been performed. Although in the described embodiment the storage means 16 are located in the process means 11, they can of course be connected to the speech synthesis means 20.

In the above embodiments, the signal station 10 receives a fire signal, etc., via a single signal line, but also several signal lines may be connected or different types of fire information means may be connected to the respective signal lines. In these cases, a program is generated for retrieving the fire information of the block names corresponding to the signal line in question, for controlling the retrieval operation by the process means 11.

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As explained above, in accordance with the present invention, messages regarding actions to be taken during a fire can be automatically issued in the form of speech, so that it becomes possible to instruct the doorman, etc., to act quickly and correctly. Normally, messages for instruction manual, fire alarm system, etc., messages for practice training, etc. may be issued on request in the form of a speech to guide the practice of the doorman, etc. In addition, if the station is connected to announcement devices, explanations of emergency devices, messages to guide to a safe place, etc. can be given.

Claims (12)

1. Signal station for a fire alarm system for alerting when the fire signal is received from fire information means, such as fire detectors or pushbuttons, characterized in that the signal station comprises: storage means (16) for storing messages which relate to measures to be taken during the fire, for storage of messages relating to the operation and processing procedures of the fire alarm system and the devices connected thereto, and to the storage of messages relating to measures to be taken during the fire; speech synthesizer (20) for synthesizing speech signals for output messages (16) of storage means (16); tai output means (18) for output speech signals as speech; manual input means (15) for pointing to an optional message of the messages stored in the storage means (16) and at normal time to provide the signal required for issuing a message to output a message pointed to; and process means (11), which receive and process the fire signal and signal required at the message output to select the messages for the fire signal, which pertain to measures to be taken during the fire, and for the signal required for a message to issue the message, of messages son stored in the storage means (16), and to control the speech synthesizing means (20) to convert the message into speech. Signal station according to claim 1 for fire alarm systems, characterized in that the speech synthesizer (20) reads from the storage means (16) a message selected by the process means (11) for synthesizing the speech signal for the Iästä message. Signal station according to claim 1 for fire alarm systems, characterized in that the storage means (16) read a message selected by the process means (11) and transmit the Iästä message to the speech synthesizing means (20). Signal station according to claim 2 for fire alarm systems, characterized in that the storage means (16) comprise a permanent memory (11b) which stores the messages in the form of speech parameters, and the speech synthesizers (20) comprise a speech synthesizer (22a) for synthesizing tai for the messages on the base of speech parameters, and a control device (22f) for reading the messages from the storage means (16) in accordance with the orders of the process means (11), and for controlling the speech synthesizer with the speech synthesizer (22a). Signal station according to claim 2 for fire alarm systems, characterized in that the storage means (16) comprise a permanent memory (11b) for storing messages as character information, and the speech synthesizer (20) comprises a speech synthesizer part (22) comprising a permanent memory (22g). for storing phonemic data and an editing and synthesizing program and a microprocessor (22) in which to read the messages out of the storage means (16) relying on the processing means (11) for editing and synthesizing the voice signals to the messages depending on the phonemic data and the editing and synthesizing program. Signal station according to claim 3 for fire alarm systems, characterized in that the storage means (16) comprise a permanent memory (22g) for storing messages in the form of speech parameters, and the speech synthesizer (22) comprises a speech synthesizer (22a) for synthesizing the output from the speech parameters. , and a control device (22f) for reading messages from the storage means (16) in accordance with the orders of the process means (11) for controlling the speech synthesizer at the speech synthesizer (22a). Signal station according to claim 3 for fire alarm systems, characterized in that the storage means (16) comprise a permanent memory (22g) for storing messages as character information, and the speech synthesizer (22) comprises a speech synthesizer part (22a) comprising a permanent memory (22g) for storing phonemic data and an editing and synthesizing program and a microprocessor (22a) for editing and synthesizing speech signals depending on the orders given by the process means (11), for the messages transmitted by the process means (11 ) in accordance with the phonemic data and the editing and synthesis programs. Signal station according to any of claims 1-7 for fire alarm systems, characterized in that it further comprises functional means (14) coupled to the process means (11) for controlling the fire alarm system and devices connected thereto, said process means (11). ) receives signals confirming the function, which confirms that the required functions are performed by the function means (14) and selects the messages according to the presence of the gain signals. Signal station according to any one of claims 1-7 for fire alarm systems, characterized in that the process means (11) comprise flag setting means for controlling the flags for the relevant signals, which require the definition of the process means as a fire signal or a signal requiring the delivery of a message. Signal station according to any of claims 1-7 for fire alarm systems, characterized in that the output means (18) for tai comprise a plurality of loudspeakers (18a, b, c) which are connected by means of coupling means coupled to the speech synthesizing means (20) and the switching function with a signal from the process means (11) or with manual control. Signal station according to any of claims 1-7 for fire alarm systems, characterized in that