DE20108451U1 - Optical smoke detector - Google Patents

Abstract

An optical smoke detector has a housing which can be mounted on the ceiling (20) of a room, a measurement chamber (54) between a lower, approximately horizontal housing wall (61), and a partitioning wall (55) which has an optical measurement path and lateral openings for entry of ambient air. A circuit board (58) is arranged spaced from, and above the partitioning wall (55) and contains, besides an electronic circuit, the optical elements (59,60) for the measurement path. A central opening (69) is provided in the partitioning wall (55) and a sound source (67) is joined via conduction lines to the circuit board (58).

Description

Optical smoke detector

The invention relates to an optical smoke detector according to claim 1.

Optical smoke detectors are known in a wide variety of designs. Usually, an optical measuring section is located in a measuring chamber into which ambient air can penetrate, but preferably hardly any outside light, and which detects when smoke penetrates the section. If such detectors are connected to a large number of other detectors to form a system, they are usually equipped with a

The central unit is connected to a smoke detector, which gives an alarm when a detector detects the presence of smoke. In many cases, however, it is also desirable to connect an acoustic alarm device directly to the detector. Such combinations are already known. Some well-known examples are discussed below.

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Deutsche Bank" *A*G Hafnburg,*No.*05 28497 (bank code 200 700 24) · Postbank Hamburg, No. 28 42 206 (bank code 200 100 20)
Dresdner Bank AG Hamburg, No. 933 60 35 (bank code 200 800 00)

which are schematically shown in the accompanying drawings according to Figures 2 to 4.

The detector shown in Fig. 2 is known from DE GM 82 10 633. The device essentially consists of a round housing 1, which has a smoke chamber 2 on one end 14 and a sound chamber 4 on the other end. A partition wall 5 runs between the smoke chamber 2 and the sound chamber 4. The light-optical elements 7, 8, which are arranged opposite one another and act together as a light barrier and are arranged on the cylindrical inner wall 16 of the housing, are housed in the smoke chamber 2. The smoke can enter through openings 6 in the end wall 14 bordering the smoke chamber 2 in the middle of the detector in order to reach the measuring light beam and to dampen its intensity. When a certain amount of smoke is present, the sound generator 3 attached to the end 15 of the adjacent sound chamber 4 is activated. The sound generator 3, which is designed as a loudspeaker, also acts as a feed pump for the smoke. For this purpose, the membrane of the sound generator is initially limited to a low vibration frequency. To support the pumping effect, the partition wall 5 contains several air passage openings 10 with one-way or non-return valves so that air can flow from the sound chamber 4 into the smoke chamber 2. The front side 15 of the sound chamber 4 also contains openings 9 serving the same purpose.

Such a smoke detector with a sounder has several disadvantages. A smoke detector is usually attached to the ceiling and must be sensitive to all radial airflow directions. However, the smoke inlet 6 arranged on one end face 14 and the sounder 3 attached to the other end face 15 do not provide for this. Furthermore, loudspeakers do not meet the requirements in terms of the vulnerability of the mechanical components, their size and, above all, the high energy required in the event of an alarm, since this type of fire detector is usually battery-operated.

The known fire detector 19 shown in Fig. 3 is attached to a ceiling 20 and consists of a base 21 and an insert 22. In the divided housing 23 of the detector, a relatively small optical measuring chamber 25 is mounted off-center in the detector housing 23 on a circuit board 24. A sound generator 29, which contains a piezo disk 29, is also arranged off-center. A cylindrical projection 27 is arranged within the detector housing 23, on whose front surface 26 the piezo disk 29 rests. The sound leaves the housing essentially parallel to the axis from an opening 28 in the front surface 26.

The known design allows for the smoke detector to be mounted on the ceiling, but has disadvantages in terms of smoke detection and sound propagation. Smoke penetrates evenly from all sides.

into the measuring chamber 25 is hindered by the inlet openings on its circumference through the sound generator 29 and the extension 27. Furthermore, the measuring chamber 25 only achieves insufficient sensitivity due to its small dimensions and the resulting smaller scattering volume that is crucial for generating the measured value. The sound is also mainly directed at the floor below the detector. However, it is expected that a smoke detector with a protected area of up to 120m ² can hear the warning tone in neighboring rooms in the event of an alarm.

The smoke detector with sounder shown in Fig. 4 is attached to the ceiling 20 using an installation base 32. The fire detector 31 has a replaceable detector insert 33. In its housing 34, the measuring chamber is attached to the circuit board 36 centrally to the axis. The smoke can enter the measuring chamber 35 through openings 37 in the cylindrical part of the housing 34. A sounder 38 is arranged offset and partly below the measuring chamber 35 above the circuit board 36 in the area of a larger diameter shoulder of the housing 34. The sound exits through side openings 39 of the housing 34.

Although this known smoke detector meets the requirements for smoke detection, it is disadvantageous in terms of sound propagation. The sound generated by the piezo disk of the sound generator 38 partially bounces off the underside of the measuring chamber 35 and is thus directed into the interior of the detector, from where it cannot be

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can escape into the detector environment. This results in a reduction in volume. Also disadvantageous is the strong direction-dependent radiation of the alarm tone through the openings 39 that are only present in front of the sounder and the shading of the alarm tone by the cylindrical part of the housing 34 surrounding the measuring chamber 35.

An alternative is indicated in Fig. 4 with a dotted line. In this case, a sound generator 40 is arranged above the circuit board 36. The sound first passes through a hole 41 in the circuit board 36 and then finds its way to the outside via housing openings.

The invention is based on the object of creating an optical smoke detector with a sound generator that has a good acoustic effect, but does not suffer any loss in terms of smoke detection. In addition, the housing shape of the smoke detector should be visually appealing.

This object is solved by the features of claim 1.

A nearly horizontal partition separates a lower measuring chamber, which extends across the width of the detector housing, from a space above the partition, which in turn is divided by the circuit board containing the electronic circuit, which is located at a distance from the partition. In this space, on the

The sound generator is arranged on the partition wall, preferably in the middle above a hole in the partition wall. The sound generator is preferably formed by a piezo disk, which is preferably supported on a cylindrical projection on the partition wall. The opening is therefore in front of the antinode of the piezo disk. The sound generated by the sound generator initially passes axially through the opening in the partition wall and is deflected in the measuring chamber and leaves the measuring chamber through lateral openings with multiple reflections. The openings are preferably arranged around the entire circumference of the detector housing, preferably at equal distances. This allows uniform radial radiation into the room in which the detector is located on the ceiling. The measuring chamber is preferably a resonance chamber, which significantly amplifies the sound effect of the sound generator.

In the smoke detector according to the invention, the sound detector is integrated into the detector in such a way that a good acoustic effect is achieved, while at the same time a functional and visually appealing symmetrical housing shape and an optimal construction of the measuring chamber are possible. The housing or attachment of the sound generator is vibration-resistant, space-saving and ensures uniform radiation of the sound. The sound radiation is essentially radial to the detection axis, resulting in a long-range, directed propagation.

Advantageous further developments of claim 1 can be found in subclaims.

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The invention is explained in more detail below with reference to a drawing.

Fig. 1 shows a section through a schematically illustrated smoke detector

after the invention.

Fig. 2 to 4 show schematically smoke detectors according to the state of the art.

The state-of-the-art smoke detectors have already been explained above. They will not be discussed further below.

In Fig. 1, a smoke detector is designated as a whole with 51. It has an installation base 52 attached to the ceiling 20 and a detector insert 53. The detector insert consists of a bowl-like lower part 65 and a cap-like cover 64. The lower part 65, which is formed from plastic material just like the cover 64, forms the outer part of the detector 51. The mentioned parts are also circular on the circumference.

A measuring chamber 54, which extends with approximately the same height, essentially unhindered across the width of the detector 51, is limited at the top by a horizontal partition 55 and at the bottom by a horizontal wall 61 of the measuring chamber housing 62. The partition 55 is supported at the edge on the measuring

chamber housing via webs 63 which form openings between them which are evenly distributed over the circumference of the detector 51. Hollow projections 56 which are open on one side and project to the rear are formed from the partition 54. They accommodate optical elements 59, 60 which are connected to a circuit board 58. The circuit board extends within the cover 64 approximately parallel to the partition 55 and at a distance from it. The measuring chamber 62 is also embedded in the shell-like lower part 65. The shell-like lower part has ribs 66 which run at a distance around the circumference and coincide with the openings formed by the support webs 63 in order to allow ambient air to enter the measuring chamber 54 and thus also smoke. The webs 63 are specially designed so that no light from the environment can enter the measuring chamber 54. An opening 69 is formed in the middle of the partition wall 55, and a hollow cylindrical projection 68 on the partition wall 55, which extends towards the circuit board 58, carries a piezo disk 67. The sound indicated by the wavy line is generated by the piezo disk 67, which first passes through the opening 69 and is guided into the measuring chamber 54. There the sound hits the inside of the measuring chamber wall 61, and is then directed to the ribs 63 by multiple reflection between the partition wall 55 and the outer wall 61 of the housing. There the sound exits through the openings essentially radially in all directions with approximately the same volume.

The insert formed from parts 64 and 65 can be removably attached to the base 52 in any known manner.

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Claims (7)

1. Optical smoke detector with - a housing which can be attached to the ceiling ( 20 ) of a room by suitable means, - a measuring chamber ( 54 ) between a lower, approximately horizontal housing wall ( 61 ) and a partition wall ( 55 ) which is spaced apart and parallel to the lower housing wall ( 61 ) and has an optical measuring path and lateral openings for the entry of ambient air, - a circuit board ( 58 ) arranged parallel to and at a distance from and above the partition wall ( 55 ), which, in addition to an electronic circuit arrangement, holds the optical elements ( 59 , 60 ) for the measuring path, the holders of which extend through openings in the partition wall ( 55 ), - a preferably central opening ( 69 ) in the partition wall ( 55 ) and - a sound generator ( 67 ) arranged above the partition wall ( 55 ) and connected to the circuit board ( 58 ) via lines. 2. Optical smoke detector according to claim 1, characterized in that the sound generator ( 67 ) is formed by a piezo crystal disk which is mounted on a hollow cylindrical projection ( 68 ) on the partition wall ( 55 ) which extends approximately coaxially to the opening ( 69 ) in the direction of the circuit board ( 58 ). 3. Optical smoke detector according to claim 1 or 2, characterized in that the measuring chamber ( 54 ) is designed as a resonance chamber. 4. Optical smoke detector according to one of claims 1 to 3, characterized in that the lateral openings of the measuring chamber ( 54 ) are distributed approximately evenly over the circumference of the measuring chamber ( 54 ). 5. Optical smoke detector according to one of claims 1 to 4, characterized in that the partition wall ( 55 ) is supported on the measuring chamber wall ( 61 ) via webs ( 63 ) on the circumference of the measuring chamber ( 54 ), which delimit the lateral openings. 6. Optical smoke detector according to one of claims 1 to 5, characterized in that the optical elements are arranged in hollow projections ( 56 , 57 ) of the partition wall ( 55 ), which have a lateral opening. 7. Optical smoke detector according to one of claims 1 to 6, characterized in that the partition wall ( 55 ) and the measuring chamber wall ( 61 ) are arranged in a shell-like lower part ( 65 ) made of plastic, which is covered by means of a cap-like cover ( 64 ) and the lower part ( 65 ) and cover ( 64 ) form an insert which can be detachably attached to a base ( 52 ) fastened to the ceiling ( 20 ) of the room.