Introduction
[0001] The invention relates to static alarm devices such as smoke, heat and/or carbon monoxide
(CO) alarm devices.
[0002] The sensing technology of such devices is typically of good quality and is reliable.
However, problems can arise due to use of the devices whereby an adequate flow of
air to be sensed does not reach the active sensor, for example smoky air not reaching
an optical chamber sensor of a smoke alarm device, hot air not reaching a temperature
sensor, or air with CO not reaching a CO sensor. This can arise if someone inadvertently
puts an obstacle in place, such as for example taping over a vent of a device while
painting and decorating, covering over a device with a false ceiling, or placing a
large item of furniture close to the device.
[0004] The invention is directed towards providing enhanced obstacle detection for alarm
devices which are suitable to be mounted in static positions to detect a condition
of ambient air.
Summary
[0005] The invention is defined in the accompanying claims 1 to 11.
[0006] The alert may be internal, to prevent proceeding with an obstacle detection test,
and/or it may be a user alert such as an audio or visual alert.
[0007] Preferably, the guide element is mounted by a plurality of pillars. Preferably, the
guide element has a first curved surface facing the housing, and said guide element
first curved surface may be generally concave.
[0008] Preferably, the housing has a curved surface facing the guide element, and the housing
curved surface may be generally convex. Preferably, the guide element is mounted substantially
symmetrically to the device longitudinal axis.
[0009] Preferably, the guide element is dish-shaped with a narrower end facing the housing.
Preferably, the guide element has a second curved surface facing away from the device
housing. Preferably, said second curved surface is generally convex.
[0010] Preferably, the guide element has a thickness and a density to act as a secondary
ultrasonic source upon ultrasonic waves being incident on the first surface.
[0011] Preferably, the vents are arranged around at least some of the circumference of the
housing with a field of emission of ultrasonic waves guided by the guide. According
to the invention, at least some of the vents are arranged so that at least some ultrasonic
waves pass through the vents.
[0012] The barrier element may be annular.
[0013] Preferably, the ultrasonic transducer is mounted in a resilient cover and said cover
engages in an aperture of a substrate which is in turn mounted to the housing.
[0014] Preferably, the resilient cover has a groove which engages a side edge of the substrate
aperture. Preferably, the ultrasonic transducer is connected to a conductor on a substrate
by a flexible wire link.
[0015] Preferably, the processor is programmed to detect ambient air instability either
before or as part of an obstacle detection operation. The processor may be configured
to record a return signal amplitude value for each of a plurality of sample points,
and to quantify variance across said values, and if said variance exceeds a threshold
determine that there is excessive ambient air instability.
[0016] Preferably, the processor is configured to determine a series of difference values
for each pair of successive values for a sample point, and to derive a sample point
variance value representative of variance for each sample point, and to compare the
derived sample point variance value with a threshold. Preferably, the derived sample
point variance value is a sum of the difference values for a sample point.
[0017] Preferably, the processor is configured to perform a plurality of scans each with
a plurality of sample points, and to determine a multi-scan derived variance value
derived from said sample point variance values. Preferably, a multi-scan derived variance
value is an average of all sample point variance values.
Detailed Description of the Invention
[0018] The invention will be more clearly understood from the following description of some
embodiments thereof, given by way of example only with reference to the accompanying
drawings in which:
Figs. 1, 2, and 3 are top perspective, top plan and side views respectively of an
optical alarm device;
Fig. 4 is a block diagram of the main functional parts of the device;
Fig. 5 is a cut-away perspective view showing the device housing, and Ultrasonic ("US")
wave guide element pathways for US waves for obstacle detection, especially in relation
to vents for ambient air entry;
Fig. 6 is a cut-away perspective view of an ultrasonic transducer, and Fig. 7 is a
perspective view of its mounting PCB in which the transducer is mounted in a manner
to minimise transfer of vibration to the PCB and to other components;
Figs. 8 to 11 are diagrams illustrating operation of the obstacle detector in terms
of emission of ultrasonic waves;
Figs. 12, 13 and 14 are perspective, side and cut-away views of an alternative alarm
device with an obstacle detector; and
Fig. 15 is a table of data from eight consecutive scans, each with 38 sample points
captured in still air, for air turbulence detection, Fig. 16 is a plot of the eight
scans overlaid using the data from Fig. 15, Fig. 17 is a table of values including
processed values, Fig. 18 is a plot showing by interrupted lines the differences in
plots of amplitude vs. time where conditions are unstable in terms of air turbulence,
and Fig. 19 is a plot of variance across multiple sample points for stable air variance,
stable air average variance, unstable air, and unstable air average variance.
[0019] Referring to Figs. 1 to 3 an alarm device 1 comprises a housing having an overall
cylindrical shape with a longitudinal axis, and with a base 2 and vents 3 arranged
circumferentially around a top part of the device. In this specification the term
"top" means the end opposed to the mounting base, even though the device may in practice
be mounted on a ceiling with the "top" facing downwardly.
[0020] The device 1 includes an obstacle detector having an ultrasonic ("US") transceiver
or "transducer" mounted on a circuit board to emit US waves, which are routed by a
guide 4 having pillars 5 supporting a dish-shaped guide element 6. The guide element
6 is mounted centrally around the longitudinal axis of the device. It has curved lower
(first) and upper (second) surfaces 10 and 11 respectively. A generally concave lower
surface 10 faces the device body 2, and a generally convex surface 11 faces away from
the device body 2. The concave surface 10 faces a top generally convex surface 12
of the housing 2 facing the guide element 6.
[0021] The invention is not concerned with the sensing details as they can be of any known
type for detecting heat, smoke, or gas which enters the vents 3. In this case the
active sensor is a smoke detector with an optical chamber.
[0022] As best shown in Figs. 1, 3, and 5 the vents 3 comprise a ring of circumferentially
arranged radial vents 3(a) and, immediately above, a ring of vents 3(b) which are
sloped to have a directional component facing radially and a directional component
facing axially (parallel to the longitudinal axis). There is a rim 9 over the vents
3, in the form of a ring mounted on pillars 13, spaced apart from the vents 3. In
this specification the term axial is intended to mean parallel to the longitudinal
axis, which in Fig. 3 is a central vertical line through the centre of the device
1.
[0023] Referring specifically to Figs. 4 and 5 the device 1 has an ultrasonic transducer
16 driven by a driver circuit 17, and is connected to a receiver amplifier circuit
18, in turn connected to a signal processing circuit 15 for delivery of signals to
a microprocessor (not shown). In this case the microprocessor is a low power, 8-bit
processor.
[0024] As shown in Figs. 5 to 7 the US transducer 16 has a cap 21 housing the active piezo
element and being surrounded by a vibration isolator in the form of a rubber sleeve
23 which protrudes downwardly to provide an internal space 25 for flexible leads 26.
The isolator 23 has a circumferential groove 27 near its lower end, the groove 27
having a width matching the thickness of a mounting PCB 22. The transducer 16 is mounted
in a hole 24 of the PCB 22, with the edge of the hole 24 engaging in the groove 27
of the rubber isolator casing 23.
[0025] As best shown in Fig. 5, the surface of the US transducer 16 is substantially co-planar
with the housing surface 12, and this provides for the US waves to be generated at
or near the external surface of the housing device body 12. The US waves therefore
do not interfere with internal components within the device body, and advantageously
the transmission and reception of US waves have clear paths from the on-axis transducer
location and reflected from the guide element 6.
[0026] A major advantage of placing the transducer 16 surface substantially flush with the
housing surface 12 instead of inside the housing, is that it minimises echo signals
caused by the ultrasound waves reflecting off the internal details of the housing.
These unwanted signals could cause false detections of objects due to the housing
itself and could be randomly increased if turbulent warm air passing through the housing
refracts the ultrasound in such a way that more of the sound energy is reflected back
to the transducer than during static airflow conditions.
[0027] Also, the mounting arrangement minimises vibration from the US transducer to the
PCB 22 by virtue of damping by the sleeve 23. Also, the flexible electrical connector
leads 26 provide electrical connection to a terminal 28 mounted on the lower surface
of the PCB 22. This further ensures that mechanical vibration is not transmitted to
the PCB. This has the effect of reducing signal "ringing" while also reducing stress
on electrical joint components, helping to ensure reliability. "Ringing" is a known
condition of US transducers, where the generated oscillations continue even after
the excitation source has been removed. For detection of near-field objects, ringing
should be reduced such that it does not interact with the returning echo signal of
interest. For a near object to be correctly detected, the ringing is preferably therefore
stopped as soon as possible after excitation.
[0028] The guide element 6, being placed so close to the US source 16 (less than 5 mm) acts
as a secondary ultrasonic source upon ultrasonic waves being incident on the first
surface 10. This aspect is assisted by the guide element 6 having a thickness of only
about 2.8mm, being located just less than 5mm at its closest from the ultrasonic source
16, and being of moulded plastics material (polycarbonate).
[0029] The top surface 11 generally has an overall taper extending proximally towards the
housing 12 and radially inwardly to the longitudinal axis (centrally and downwardly
as viewed in Fig. 3 for example), and as noted above has locally between its rim and
the centre (longitudinal axis) a slight convex shape as viewed in section. The slight
convex shape is not essential, but it is preferred that the element 6 has an overall
dish shape tapered distally from the housing 12 and radially from the longitudinal
axis (upwardly and outwardly as viewed in for example Fig. 3). The lower surface 10
is also tapered generally proximally and radially towards the housing at the longitudinal
axis (downwardly and inwardly as viewed for example in Fig. 3). Locally between the
element rim and the longitudinal axis the surface 10 has a slight concave shape as
viewed in section, but again this is not essential. Again, the overall guide element
configuration is dish-shaped.
[0030] Use of the obstacle detector is now described with reference to Figs. 5 and 8 to
11, which are diagrammatic views illustrating paths of US waves emitted by the transducer
16. Advantageously, the US waves propagate radially from the longitudinal axis of
the device, out from a space between the guide element 6 lower surface 10 and the
housing 2 top surface 12. This wave propagation path includes above and below the
rim 9 and through the vents 3(a) and 3(b). Blockage or taping of either the axial
or radial vents creates a new surface off which the outgoing US wave can strike, resulting
in an echo that is measurable, thereby detecting blockages. This detects for example
taping over the vents (which may be inadvertently left in place by a decorator). Also,
as shown in Figs. 11 (a) and 11(b) such waves will encounter an obstacle Y parallel
with the longitudinal axis, in this case vertical. Upon encountering an obstacle,
the waves are reflected back much more quickly than if there were no obstacle. The
transducer 16 operates with the receiver amplifier circuit 18 to detect such early
reflections in a manner which is well known
per se in the art.
[0031] The "field of view" for the single transducer 16 therefore includes all radial directions
from the device longitudinal axis, allowing detection of obstacles both on the device
itself (such as tape) or nearby.
[0032] Moreover, the guide element 6 also acts as a secondary US wave source due to its
vibration in response to the waves which are incident on its lower surface 10 facing
the transducer 16. This is primarily due to the short distance between the US transducer
16 and the guide element 6 (less than 5mm at its closest, and preferably in the range
of 1.5mm to 4mm) and it is also helped by the fact that the guide element is thin
enough to vibrate. In this case the thickness of the element is about 2.8mm and it
is of plastics (polycarbonate) composition, thereby allowing it to vibrate.
[0033] This causes US waves to propagate axially from the device, as shown in Figs. 9 to
11. This allows further extension of the field of view, allowing the obstacle detector
to detect horizontal obstacles X such as shown in Figs. 10(a) and 10(b). The returning
echo signal (Fig. 10(b)) encounters the guide element 6 upon which the vibration is
re-transmitted back to the US transducer 16 for detection. The return signal is further
enhanced from horizontal obstacles X by way of the angled edge of the outer rim 9
and/or angled vent fins.
[0034] Another advantageous aspect of the device 1 is that by providing vents which face
radially and also vents which at least partially face axially there is less chance
of all of the vents being accidently taped. This is further improved by virtue of
the rim 9, which acts as a spaced-apart barrier to help reduce chances of the vents
being taped over such that air entry is completely blocked or blocked to an extent
that severely hinders the operation of the alarm.
[0035] With the rim 9 effectively preventing convenient access to the radial and axial vents,
tape applied around the circumference of the unit is no longer sufficient to block
some or all of the vents from air entry, since there still remains a viable air entry
path in the axial direction.
[0036] Referring to Figs. 12 to 14 an alternative device 100 has a housing 102 with a guide
104 akin to the guide 4 of Figs. 1 to 13. In this case there are vents 103 which face
both radially and axially. Spacers 130 are arranged to extend generally axially between
the vents 103, thereby helping to prevent taping of the vents 103 while also allowing
propagation of US waves through and over the vents.
[0037] Another advantageous aspect of the device is that the processor is programmed to
detect ambient air changes and turbulence, thereby providing an indication of reliability
of the US obstacle detection measurement. An obstacle detection test may be inaccurate
if the ambient air is unstable, for example by flowing at an excessive flow rate,
and/or rapid changes in air temperature (relative to the steady state temperature
of the unit or object under test), by for example a nearby air conditioning unit.
Such air flow may render the obstacle detection inaccurate because the relevant changes
in air characteristics (temperature, velocity, refractive index) would affect US beam
uniformity, signal intensity and propagation time to and from the obstacle. This makes
accurate US detection of objects, and also calculation of object distance from echo
return time, unreliable.
[0038] In this embodiment the air stability test is integrated with the obstacle detection
test, the processor firstly analysing the US return signal values to initially determine
if the ambient air is sufficiently stable. If sufficiently stable, the processor proceeds
to use the values to determine if there is an obstacle.
[0039] It is also envisaged that the processor may carry out an air stability test as a
discrete test to decide whether to carry out an obstacle detection test. For example,
the processor may be programmed to carry out an obstacle detection routine once per
day, thereby consuming valuable electrical power only for a number of seconds once
per day.
[0040] For each obstacle detection test the processor performs a number of ultrasonic scans
separated by a small (about 1msec) delay. To reduce the effect of signal noise, the
results of the scans are summed and averaged to a single data set upon which obstacle
detection logic is performed. Since averaging requires multiple scans, the system
uses these multiple scans more advantageously to determine the ambient air stability,
thus acting as an indicator of reliability for obstacle detection measurements.
[0041] In each scan, the US transducer is driven with a number of pulses, after which the
processor samples and stores the amplitude of the returning signal as a function of
time. The processor then performs calculations to quantify the extent of amplitude
variation between the same sample points on successive scans. Variance or Standard
Deviation across all scans is then calculated for each data point.
[0042] It is useful to, for example, sum or average the variance, or standard deviation
values to yield a single value for the entire scan. This value is compared to a threshold
to determine if the ambient air properties were stable or unstable during the time
of the scans.
[0043] In stable air conditions the variation from measurement to measurement should be
small across the full scan, yielding a low average variance value. As instability
in the air increases the variance increases. The threshold level is determined empirically,
based on acceptable limits of detection and repeatability of the system.
[0044] If the result of the calculation is less than the threshold, the scan is "Stable"
and so the average scan is accepted as a valid obstacle detection measurement. If
the result is "Unstable", the obstacle detection measurement is not accepted and the
measurement should be repeated. This may be repeated at intervals until a valid ("Stable")
measurement is obtained.
[0045] Fig. 15 is a table of return signal amplitude values for 6 of the 36 sample points
in 8 scans. Each column is a scan and each row contains the return values for a certain
sample point across all of the scans. For example, Row 3 of the Fig. 15 table shows
the return signal amplitude values for the first sample point for all 8 scans.
[0046] Referring to Fig. 16 variations in amplitude of the return signals is shown.
[0047] To determine the level of variability, the processor measures the absolute difference
(or 'delta' in reference to Fig. 15) between a particular sample point return signal
value of one scan and the next, comparing each scan to the previous, for all 8 scans
(in this case). There may be one column for each delta value across the 8 scans, so
therefore 7 columns of delta values, as shown in Fig. 17. The right-hand column of
Fig. 17 has the value for the sum of the deltas for each row (i.e. the sum of the
seven-delta series of values for each sample point).
[0048] Fig. 18 shows examples of amplitude signals for stable and unstable conditions. The
higher and lower amplitudes shown for the unstable condition indicate how the signal
can vary relative to the true signal (stable condition) as a result of air instability,
caused by, for example, an air-conditioning blower. In this case the amplitude variability
occurs rapidly (for example, less than 1 sec), so fast successive scans can therefore
measure these variances. This is in contrast to other environmental instability such
as room temperature changes which generally occur over minutes or hours and would
generally have little effect on the amplitude of the return signal (but may change
the echo return time if compensation for temperature is not included).
[0049] Unwanted amplitude variation of a signal is effectively noise, and an alternative
approach may be to minimize such noise by averaging the signals. However, if the variation
in amplitude is a significant fraction of the true amplitude, then the average signal
may be a poor representation of the actual signal. This is especially true if the
number of scans or samples is limited by hardware, power consumption or memory, such
as with inexpensive 8-bit microcontrollers. Experimentally it was found that averaging
of 16 times was insufficient to remove the noise caused by air instability from air
conditioning unit and could lead to false detections or misinterpretation of the signals.
Hence, the approach of determining and analysing variance is preferred.
[0050] Fig. 19 shows the values of variance represented by arbitrary units. The average
variance for stable air is approximately 2 units and that for unstable air is about
10 units. These units allow the processor to have a threshold setting for average
variance above which it decides that the air is excessively unstable.
[0051] The following is an example of simplified pseudo code for the turbulence testing
performed by the processor.
- Drive transducer with x number of pulses.
- Start sampling via ADC.
- Take 40 samples with time interval of 50µ sec (total time of sampling is therefore
2 msec per scan).
- Store samples in array.
- Wait 5 msecs.
- Repeat the above procedure 16 times to yield an array of 16 x 40 samples.
- For each sample point, calculate the absolute difference between each point on successive
scans.
- Sum the 16 absolute difference values to yield a single value for each of the 40 sample
points. The resulting array is 1 × 40.
- This array can be averaged by dividing each value by 16 or used as is.
- The resulting array can be further simplified to a single value by averaging all samples
into one, i.e. sum the 40 sample points and divide by 40.
- This "turbulence" value gives an indication of the average absolute difference across
all sample points.
- This single value is compared to an "instability threshold".
- If "turbulence" value > "instability threshold" raise flag to alert system or user,
abort obstacle detection.
- If "turbulence" value < "instability threshold", proceed to process the previously
stored 16-scan data for purposes of obstacle detection.
[0052] The invention is not limited to the embodiments described but may be varied in construction
and detail. For example, even though the US guide provides a wide field of view for
the single transducer there may be one or more additional transducers. It is not essential
that the top surface or the bottom surface of the guide element be curved as viewed
in a plane from the longitudinal axis towards the edge, and if either is curved the
shape may be convex or concave between the longitudinal axis and the edge.
1. An alarm device to detect a condition of ambient air, the alarm device comprising:
a housing (2) having a longitudinal axis and containing a sensor and having vents
(3) for access by ambient air to the sensor,
a signal processing circuit (15) with a processor linked with the sensor,
a power supply for the circuit and the sensor,
an obstacle detector for detecting presence of an unwanted obstacle in the flow of
ambient air to said sensor, the obstacle detector comprising:
an ultrasonic transducer (16) mounted in or on the device having a field of emission
outside of the device,
a processor (18, 19) in the circuit (22) and linked with the ultrasonic transducer
to monitor ultrasonic return values and process the ultrasonic return values to determine
if any of the ultrasonic return values have been reflected by an unwanted obstacle,
wherein the processor is configured to generate an alert to indicate presence of such
an obstacle which may affect access of ambient air to the sensor through the vents,
and
a guide (4) mounted to the housing substantially symmetrically to the device longitudinal
axis and comprising a guide (6) element spaced-apart from the housing to reflect emitted
ultrasonic waves in radial directions relative to the longitudinal axis,
characterized in that,
at least some of the vents (3(b)) are arranged so that at least some ultrasonic waves
pass through the vents,
the vents include vents (3(a)) which are primarily facing radially and vents (3(b))
which at least have a directional component facing axially, and
the housing includes a barrier (9) to render application of tape to the vents difficult,
said barrier comprising a barrier element mounted by pillars (13) so that the barrier
is spaced apart from at least some of said vents.
2. An alarm device as claimed in claim 1, wherein the guide element is dish-shaped with
a narrower end facing the housing, and the housing has a curved generally convex surface
(12) facing the guide element.
3. An alarm device as claimed in claim 2, wherein the guide element is mounted by a plurality
of pillars (5) and is spaced from the ultrasonic transducer by less than 5mm.
4. An alarm device as claimed in claim 3, wherein the guide element has a surface (10)
facing the housing which has a concave curve from the longitudinal axis towards the
edge of the guide element, and the transducer (16) has a surface which is substantially
flush with the housing surface (12).
5. An alarm device as claimed in any preceding claim, wherein the vents are arranged
around at least some of the circumference of the housing, and the barrier element
(9) is annular.
6. An alarm device as claimed in any preceding claim, wherein the ultrasonic transducer
is mounted in a resilient cover (23) and said cover engages in an aperture (24) of
a substrate (22) which is in turn mounted to the housing.
7. An alarm device as claimed in claim 6, wherein the resilient cover (23) has a groove
(27) which engages a side edge of the substrate aperture, and wherein the ultrasonic
transducer is connected to a conductor (28) on a substrate by a flexible wire link
(26).
8. An alarm device as claimed in any preceding claim, wherein the processor (18, 19)
is programmed to detect ambient air instability either before or as part of an obstacle
detection operation, and wherein the processor is configured to record a return signal
amplitude value for each of a plurality of sample points, and to quantify variance
across said values, and if said variance exceeds a threshold determine that there
is excessive ambient air instability.
9. An alarm device as claimed in any claim 8, wherein the processor (18, 19) is configured
to determine a series of difference values for each pair of successive values for
a sample point, and to derive a sample point variance value representative of variance
for each sample point, and to compare the derived sample point variance value with
a threshold.
10. An alarm device as claimed in claim 9, wherein the derived sample point variance value
is a sum of the difference values for a sample point.
11. An alarm device as claimed in any of claims 8 to 10, wherein the processor (18, 19)
is configured to perform a plurality of scans each with a plurality of sample points,
and to determine a multi-scan derived variance value derived from said sample point
variance values, and wherein a multi-scan derived variance value is an average of
all sample point variance values.
1. Alarmvorrichtung zur Erkennung eines Zustands von Umgebungsluft, wobei die Alarmvorrichtung
Folgendes umfasst:
ein Gehäuse (2) mit einer Längsachse, das einen Sensor enthält und Lüftungsöffnungen
(3) für den Zugang der Umgebungsluft zu dem Sensor aufweist,
eine Signalverarbeitungsschaltung (15) mit einem mit dem Sensor verbundenen Prozessor,
eine Stromversorgung für die Schaltung und den Sensor,
einen Hindernisdetektor zum Erkennen der Präsenz eines unerwünschten Hindernisses
in der Strömung von Umgebungsluft zu dem genannten Sensor, wobei der Hindernisdetektor
Folgendes umfasst:
einen Ultraschallwandler (16), der in oder an der Vorrichtung montiert ist und ein
Emissionsfeld außerhalb der Vorrichtung hat,
einen Prozessor (18, 19) in der Schaltung (22), der mit dem Ultraschallwandler verbunden
ist, um Ultraschall-Rückkehrwerte zu überwachen und die Ultraschall-Rückkehrwerte
zu verarbeiten, um festzustellen, ob Ultraschall-Rückkehrwerte von einem unerwünschten
Hindernis reflektiert wurden, wobei der Prozessor zum Erzeugen eines Alarms konfiguriert
ist, um die Präsenz eines solchen Hindernisses anzuzeigen, das den Zugang von Umgebungsluft
zum Sensor durch die Lüftungsöffnungen beeinträchtigen kann, und
eine Führung (4), die im Wesentlichen symmetrisch zur Längsachse der Vorrichtung am
Gehäuse montiert ist und ein vom Gehäuse beabstandetes Führungselement (6) umfasst,
um emittierte Ultraschallwellen in radiale Richtungen relativ zur Längsachse zu reflektieren,
dadurch gekennzeichnet, dass
zumindest einige der Lüftungsöffnungen (3(b)) so angeordnet sind, dass zumindest einige
Ultraschallwellen durch die Lüftungsöffnungen passieren,
die Lüftungsöffnungen in erster Linie radial weisende Lüftungsöffnungen (3(a)) und
Lüftungsöffnungen (3(b)) mit zumindest einer axial weisenden Richtungskomponente umfassen,
und das Gehäuse eine Barriere (9) umfasst, um das Anbringen von Band an den Lüftungsöffnungen
zu erschweren, wobei die Barriere ein Barrierenelement umfasst, das durch Säulen (13)
montiert ist, so dass die Barriere von zumindest einigen der Lüftungsöffnungen beabstandet
ist.
2. Alarmvorrichtung nach Anspruch 1, wobei das Führungselement schalenförmig ist, wobei
ein schmaleres Ende dem Gehäuse zugewandt ist, und das Gehäuse eine gekrümmte, allgemein
konvexe Oberfläche (12) aufweist, die dem Führungselement zugewandt ist.
3. Alarmvorrichtung nach Anspruch 2, wobei das Führungselement durch mehrere Säulen (5)
montiert ist und vom Ultraschallwandler um weniger als 5 mm beabstandet ist.
4. Alarmvorrichtung nach Anspruch 3, wobei das Führungselement eine dem Gehäuse zugewandte
Oberfläche (10) mit einer von der Längsachse zum Rand des Führungselements konkaven
Krümmung aufweist, und der Wandler (16) eine Oberfläche aufweist, die im Wesentlichen
bündig mit der Gehäuseoberfläche (12) ist.
5. Alarmvorrichtung nach einem vorherigen Anspruch, wobei die Lüftungsöffnungen zumindest
um einen Teil des Umfangs des Gehäuses angeordnet sind und das Barrierenelement (9)
ringförmig ist.
6. Alarmvorrichtung nach einem vorherigen Anspruch, wobei der Ultraschallwandler in einer
elastischen Abdeckung (23) montiert ist und die genannte Abdeckung in eine Öffnung
(24) eines Substrats (22) eingreift, das wiederum am Gehäuse montiert ist.
7. Alarmvorrichtung nach Anspruch 6, wobei die elastische Abdeckung (23) eine Nut (27)
aufweist, die in eine Seitenkante der Substratöffnung eingreift, und wobei der Ultraschallwandler
mit einem Leiter (28) auf einem Substrat durch eine flexible Drahtverbindung (26)
verbunden ist.
8. Alarmvorrichtung nach einem vorherigen Anspruch, wobei der Prozessor (18, 19) zum
Erkennen einer Umgebungsluftinstabilität entweder vor einem oder als Teil eines Hinderniserkennungsvorgang(s)
programmiert ist, und wobei der Prozessor zum Aufzeichnen eines Rückkehrsignalamplitudenwertes
für jeden von mehreren Abtastpunkten und zum Quantifizieren von Varianz über die Werte
und, wenn die genannte Varianz einen Schwellenwert überschreitet, zum Feststellen
konfiguriert ist, dass eine übermäßige Umgebungsluftinstabilität vorliegt.
9. Alarmvorrichtung nach Anspruch 8, wobei der Prozessor (18, 19) zum Bestimmen einer
Reihe von Differenzwerten für jedes Paar aufeinander folgender Werte für einen Abtastpunkt
und zum Ableiten eines die Varianz für jeden Abtastpunkt darstellenden Abtastpunkt-Varianzwertes
und zum Vergleichen des abgeleiteten Abtastpunkt-Varianzwertes mit einem Schwellenwert
konfiguriert ist.
10. Alarmvorrichtung nach Anspruch 9, wobei der abgeleitete Abtastpunkt-Varianzwert eine
Summe der Differenzwerte für einen Abtastpunkt ist.
11. Alarmvorrichtung nach einem der Ansprüche 8 bis 10, wobei der Prozessor (18, 19) zum
Durchführen mehrerer Scans jeweils mit mehreren Abtastpunkten und zum Bestimmen eines
von den genannten Abtastpunkt-Varianzwerten abgeleiteten Multiscanabgeleiteten Varianzwertes
konfiguriert ist, und wobei ein Multiscan-abgeleiteter Varianzwert ein Durchschnitt
aller Abtastpunkt-Varianzwerte ist.
1. Un dispositif d'alarme destiné à la détection d'une condition d'air ambiant, le dispositif
d'alarme comprenant :
un boîtier (2) possédant un axe longitudinal et contenant un capteur et possédant
des évents (3) destinés à un accès par l'air ambiant au capteur,
un circuit de traitement de signaux (15) avec un processeur relié au capteur,
un bloc d'alimentation électrique destiné au circuit et au capteur,
un détecteur d'obstacle destiné à la détection de la présence d'un obstacle indésirable
dans le flux d'air ambiant vers ledit capteur, le détecteur d'obstacle comprenant
:
un transducteur à ultrasons (16) monté dans ou sur le dispositif possédant un champ
d'émission à l'extérieur du dispositif,
un processeur (18, 19) dans le circuit (22) et relié au transducteur à ultrasons de
façon à surveiller des valeurs en retour à ultrasons et à traiter les valeurs en retour
à ultrasons de façon à déterminer si certaines des valeurs en retour à ultrasons ont
été réfléchies par un obstacle indésirable, où le processeur est configuré de façon
à générer une alerte destinée à indiquer la présence d'un tel obstacle qui peut affecter
un accès de l'air ambiant au capteur au travers des évents, et
un guide (4) monté sur le boîtier sensiblement symétriquement à l'axe longitudinal
du dispositif et comprenant un élément de guide (6) espacé du boîtier de façon à réfléchir
des ondes à ultrasons émises dans des directions radiales par rapport à l'axe longitudinal,
caractérisé en ce que,
au moins certains des évents (3(b)) sont agencés de sorte qu'au moins certaines ondes
à ultrasons passent au travers des évents,
les évents comprennent des évents (3(a)) qui sont principalement orientés radialement
et des évents (3(b)) qui au moins possèdent un composant directionnel orienté axialement,
et le boîtier comprend une barrière (9) destinée à rendre difficile l'application
d'un ruban aux évents, ladite barrière comprenant un élément de barrière monté à l'aide
de piliers (13) de sorte que la barrière soit espacée d'au moins certains des évents.
2. Un dispositif d'alarme selon la Revendication 1, où l'élément de guide est de forme
parabolique avec une extrémité plus étroite orientée vers le boîtier, et le boîtier
possède une surface convexe généralement incurvée (12) orientée vers l'élément de
guide.
3. Un dispositif d'alarme selon la Revendication 2, où l'élément de guide est monté à
l'aide d'une pluralité de piliers (5) et est espacé du transducteur à ultrasons de
moins de 5 mm.
4. Un dispositif d'alarme selon la Revendication 3, où l'élément de guide possède une
surface (10) orientée vers le boîtier qui possède une courbe concave à partir de l'axe
longitudinal vers le bord de l'élément de guide, et le transducteur (16) possède une
surface qui est sensiblement à fleur avec la surface du boîtier (12).
5. Un dispositif d'alarme selon l'une quelconque des Revendications précédentes, où les
évents sont agencés autour d'au moins une partie de la circonférence du boîtier, et
l'élément barrière (9) est annulaire.
6. Un dispositif d'alarme selon l'une quelconque des Revendications précédentes, où le
transducteur à ultrasons est monté dans un couvercle élastique (23) et ledit couvercle
vient en prise dans une ouverture (24) d'un substrat (22) qui est à son tour monté
sur le boîtier.
7. Un dispositif d'alarme selon la Revendication 6, où le couvercle élastique (23) possède
une rainure (27) qui entre en prise avec un bord latéral de l'ouverture du substrat,
et où le transducteur à ultrasons est raccordé à un conducteur (28) sur un substrat
par une liaison filaire souple (26).
8. Un dispositif d'alarme selon l'une quelconque des Revendications précédentes, où le
processeur (18, 19) est programmé de façon à détecter une instabilité de l'air ambiant
soit avant ou en tant que partie d'une opération de détection d'obstacle, et où le
processeur est configuré de façon à enregistrer une valeur d'amplitude de signal en
retour pour chaque point d'échantillonnage d'une pluralité de points d'échantillonnage,
et à quantifier une variance sur lesdites valeurs, et si ladite variance dépasse un
seuil, déterminer qu'il existe une instabilité de l'air ambiant excessive.
9. Un dispositif d'alarme selon la Revendication 8, où le processeur (18, 19) est configuré
de façon à déterminer une série de valeurs de différence pour chaque paire de valeurs
successives pour un point d'échantillonnage, et à dériver une valeur de variance de
point d'échantillonnage représentative d'une variance pour chaque point d'échantillonnage,
et à comparer la valeur de variance de point d'échantillonnage dérivée à un seuil.
10. Un dispositif d'alarme selon la Revendication 9, où la valeur de variance de point
d'échantillonnage dérivée est une somme des valeurs de différence pour un point d'échantillonnage.
11. Un dispositif d'alarme selon l'une quelconque des Revendications 8 à 10, où le processeur
(18, 19) est configuré de façon à exécuter une pluralité de balayages, chacun d'eux
avec une pluralité de points d'échantillonnage, et à déterminer une valeur de variance
dérivée multi-balayage qui est dérivée desdites valeurs de variance de point d'échantillonnage,
et où une valeur de variance dérivée multi-balayage est une moyenne de la totalité
des valeurs de variance de point d'échantillonnage.