SE512882C2 - Alarm - Google Patents

Abstract

Fire alarm for persons with impaired hearing including an activating smoke detector and a loudspeaker that is driven by a sound circuit including amplifier and a sound generating part. The sound generating part is so programmed that it delivers both square waves and sawtooth waves with different frequencies below or at 500 Hz. The result is a very powerful wobbling alarm sound that can be heard of the majority of persons with impaired hearing. In many cases also vibrations that are generated by the alarm can be "felt" in other ways than by hearing, in particular by different objects being oscillated.

Description

512 882 ' 2 shaped pulses also supply one or more signals with tooth shape and low frequency, for example consistent with those for the square road, the corresponding additional sound is obtained in it low frequency range that facilitates the audibility of people with impaired hearing.

You can also imagine sounding the sawtooth wave or waves have a slightly different frequency in relation to the square wave so that one also obtains an interference that gives one in time varying amplitude and shape of the different sound pulses, respectively tive tones. This eliminates the habituation effect that the ear has which means that a continuous tone or other sound can is turned off by the ear so that you do not notice it. By just applying turn a sawtooth-shaped shape for the interfering further the sound wave obtains a greater variation in the sound and the chances of that a person with hearing loss should hear and notice it increases.

By further using low tones, there is during happiness circumstances also the possibility of different objects in the room can swing with and thereby through its vibrations make a person with hearing loss pay attention to the alarm even if he or she can not hear the alarm. For people with such impaired hearing however, it is advisable to also use lights or vibrator alarms for to increase security.

By a suitable further development of the inventive idea provide the alarm with a discharge flash is available in the usual way the possibility for a non-hearing person to see the alarm and in addition, the possibility for a hearing-impaired person to receive confirmation that it is the alarm he or she hears.

Additional advantages of the invention as well as further development It is apparent from the claims as well as from the following description of a preferred embodiment of the invention in connection to the attached drawings. In this case, fig_¿ shows an alarm in accordance with the invention in plan view and Fig. 2 the same plant seen from a gable.

The alarm shown in Fig. 1 comprises a battery unit 1, a electronic sound circuit with amplifier 2, a smoke detector 3 and a flashljbs 4. The amplifier 2 is connected to a speaker 5 which is mounted with a resonator 6 consisting of one from the speaker - 512 882 ' 3 projecting cylindrical tube with a diameter corresponding to the speaker's output port. The resonator tube provides together with the depth of the loudspeaker is suitable for the desired frequencies nanslängd. In front of the mouth of the resonator in the opposite speaker the end is a speaker grille 7 arranged.

The fire alarm shown in the drawings works in this way that in the event of a fire, the smoke detector 3 detects as appropriate is of the ionizing type to ensure long operating time, the smoke.

The smoke detector 3 activates both the flash light 4 and the sound circuit associated amplifiers. The amplifier feeds the speaker with one signal in accordance with the invention. The signal consists of square waves mixed with a sawtooth-shaped waves and gives a wobbling loud sound. The square wave.in itself sounds a bit like a mains frequency humming from a poorly mounted device but with a higher frequency, while the sawtooth-shaped wave gives a more normal tone.

Together, however, the varied and easily recognizable only the alarm signal which is not likely to be confused with the hum from the refrigerator or the like. By using the resonator, considerably amplified for the sounds or tones that are interesting from an audibility point of view for people with hearing impairments sel. This reinforcement is shown in the attached table which is measured for an alarm sound in accordance with the invention.

As can be seen from the table, the straight cylindrical can be shown the resonator tube is replaced with an outwardly conical one from the outside of the speaker tapered tubes, with some further reinforcement of the interesting frequencies are achieved. Converted to a maximum effect of l0W applied to the speaker element, this means that the the pressure levels in the ÉOHZ octave at lm distance would be in large play order 95dB. The conical resonator produces a slightly higher sound pressure levels than the straight one in the 500Hz band and slightly lower in the 1000 - 2000Hz band. From an audibility point of view, the 50OHz band is the most important guest, as shown by a comparison of the sound levels of the sound sensors in relation to the thresholds in the far right column.

As can be seen, the measured sound levels at 500Hz mean 75 - 79dB above normal hearing threshold while at 250 Hz above values 49 - 61dB above a normal hearing threshold. At free sound propagation reduces the volume by 6dB at each distance 512 882 ' 4 doubling. Indoors, the sound level decreases less due to reflections in floors, ceilings, etc. The maximum sound level at a distance of about 10 meters with an applied power of nominal IOW amounts to at least 75-80dB SPL in the 500Hz band. In other words, the signal can be estimated to be well audible for people with a hearing loss of 50dB at 5OOHz. In this way, the signal can be perceived by the vast majority of all hearing-impaired people because the dominant hearing-impaired types involve relatively well-preserved hearing thresholds in low-frequency the area.

The electrical signals, i.e. in particular the electrical edge pulses and sawtooth pulses formed and mixed in the sound circuit and amplified with the associated amplifier and resonator can either be stored digitally as a recorded and tested audio frequency that is then played over and over again upon activation or as mathematical functions for the voltage or current signals which the speaker must be fed with.

In the present case, both the sawtooth shape and the edge shape symmetrical.

Within the framework of the inventive concept, it is also conceivable that during the alarm, the frequency varies either for square wave or sawtooth wave so that a varied frequency is obtained in the wobble land for the sound even more avoiding that this is perceived as continuous and therefore easily missed.

At an output power for the alarm of 10 W, the alarm can be on and heard for a long time when alarmed and with a high volume even with moderate battery size.

The device described above is intended to be arranged as one individual fire alarm, for example at the home of a person with sat hearing.

Within the scope of the inventive concept, the audio frequencies used are varied in different ways and tested to produce the best possible hearing for people with hearing loss. In the extreme case can it even be imagined that a hearing impaired person can have their own alarm signal tested if he has difficulty perceiving the normal alarm the signal for the hearing impaired. Appropriately, however, the alarm signal should be conditionally standardized so that a hearing impaired person realizes that is a fire alarm or other alarm he hears regardless of whether he down at home, in hospital e t c.

The invention provides in relation to the known and used improved security for the vast majority, and a cost per alarm which is only a fraction of what a vibrator alarm costs.

Claims (10)

512 882 _ 6 P A T E N T K R A V Alarms, in particular fire alarms for hearing impaired persons, characterized by the emission of sound consisting of one or more square waves and one or more sawtooth waves. Alarm according to Claim 1, characterized in that the frequencies of the sound waves are in the range 100 - 50OHz. Alarm according to one of the preceding claims, characterized in that the waves are symmetrical. Alarm according to one of the preceding claims, characterized in that for square waves and / or sawtooth waves the frequencies are 100, 200, 300 and SOOHZ. Alarm according to one of the preceding claims, characterized in that a resonator is arranged in front of a sound-emitting loudspeaker with such a length that amplification is obtained in a low frequency range. Alarm according to claim 5, characterized by the resonator is conically tapered from the speaker. Alarm according to one of the preceding claims, characterized in that it is provided with a flash to enable checking whether a heard alarm is correct or not. Alarm according to one of the preceding claims, characterized in that one or more frequencies for sawtooth waves and / or square waves are varied during the sound emission. Alarm according to one of the preceding claims, characterized in that it is assembled with a smoke detector and is powered by batteries so that it can be suspended from the ceiling in a known manner. Alarm according to one of the preceding claims, characterized in that the alarm sound is in particular a digitally recorded and stored sound frequency. Table Sound levels at ch distance straight from the front and 90 ° from the side in an echo-free measuring room. Sound pressure level is stated in dB re. 20 pPa for a 1V RMS electrical signal voltage to the sound sensor. Octave- Straight resonator Conical resonator Normal band- hearth- frequency kel i (Hz) Measured Measured Measured Measured freely from front to front from sound field from side to side 63 48 47 49 46 37.5 125 58 50 59 48 22 250 72 60 72 64 11 500 80 79 83 82 4 1 000 68 70 66 68 2 2 000 69 61 66 63 -1.5 4 000 66 53 65 52 -6.5 8 000 59 41 56 40 11.5 16 000 43 <30 42 <30 43,5 A-vägc vs' 77 so so - c-vägt sl so 84 83 -