EP0142827A1 - Automatic fire sensor, and method for the manufacture of automatic fire sensors - Google Patents

Abstract

Automatic fire sensor having a laminar circuit substrate (1) which is installed in the sensor housing (9) and which incorporates electronic components (2) and a plurality of contact areas (13) on the side facing the sensor base (26) and components of the physical-electrical convertor (3, 4, 17a) on the opposite side, which together form a convertor assembly (14). The latter has, on the side of the electrical components (2), a sealant elastic envelope (5) which grips round the peripheral edge (1a) of the circuit substrate (1). The sensor housing (9) contains axially prestressed (15) contact pins (11) with points (11a) which penetrate the envelope (5) and connect the contact areas (13). The convertor assembly (14) is non-positively pressed against the housing rim (9a) at the peripheral edge (1a) of the circuit substrate (1) by a fixing element (7). The convertor assemblies (14) are manufactured and adjusted in multiples, at least one convertor group (14) being introduced into a simulation chamber (21) in which a defined fire characteristic quantity (23) is simulated for the adjustment operation, and then isolated. One convertor assembly (14) is installed in each case in the sensor housing (9), together with a possible additional convertor element (17). <IMAGE>

Description

The invention relates to an automatic fire detector with a base, with a detector housing in which a plurality of detector connection contacts are arranged, with a detector circuit arrangement which has electronic components, with a physical-electrical converter, - with a measuring chamber and a housing cover, and on one Process for the production of automatic fire detectors ..

Automatic fire detectors indicate a physical-electrical converter that measures the fire parameter, e.g. Measures heat, smoke or radiation and converts it into electrical signals, as well as electronic circuitry that further processes the electrical signals. In order to ensure correct, reliable work and to comply with the relevant regulations, the sensitivity or response sensitivity of such detectors must be kept within very narrow limits. Therefore, the inevitable exemplary tolerances, for example of the components, in particular the converter elements, must be compensated for by a function comparison. Either a certain operating point of the evaluation electronics is set or the gain of an amplifier is individually adapted to the sensitivity of the associated transducer elements.

Such an adjustment is generally carried out by adjusting potentiometers or by soldering adjustment elements on largely completed detectors. A before Adjusting the electronic circuit is not useful in most cases because the essential tolerances are caused by the converter elements. The adjustment is therefore carried out on the assembled, functional detector. However, this is relatively complex and cumbersome. The adjustment elements must be accessible from the outside, which requires preliminary construction work. For example, soldering support points for the adjustment elements or holes in the detector housing must be provided for reaching through the positioning tools. After the adjustment, ie after the adjustment process, the adjustment elements must be covered to prevent subsequent manipulation. The adjustment of a detector can therefore only be partially automated. The adjustment elements are often soldered in by hand. Such a comparison of fire detectors is very complex and therefore very expensive.

The object of the invention is to design an automatic fire detector and to specify a manufacturing method that a fully automatic function comparison is possible.

This object is achieved according to the invention in an automatic fire detector described at the outset by arranging the electronic components and a plurality of contact surfaces on the base side and the elements of the physical-electrical converter on the opposite side on a flat circuit carrier arranged in the detector housing and together a converter assembly form that the converter assembly on the electrical side. Components has a sealing elastic sheath that engages around the outer edge of the circuit carrier and forms a sealing bead, the sheath resting on the contact surfaces in the area of the contact pin that is biased in the axial direction in the detector housing te are arranged with tips that pierce the sheath and form an electrical connection with the contact surfaces, and that the transducer assembly on the outer edge of the circuit carrier is pressed non-positively with a fastener against the housing edge.

In the fire detector according to the invention, which i.a. has a circuit carrier, the electrical components and the contact surfaces are arranged on the one side, which faces the base, and the elements of the physical-electrical converter on the other side of the circuit carrier. Together, this forms the transducer assembly, which is arranged tightly in the detector housing with the component side. For this purpose, the converter assembly is provided on the component side with a sealing, elastic sleeve, which encompasses the outer edge of the circuit carrier. In the area of the contact surfaces, the sheath lies flat on it, so that contact pins arranged in the detector housing pierce the sheath with their tips and contact the transducer module used in the detector. For this purpose, the contact pins are resiliently biased in the axial direction. The outer edge of the converter assembly sits non-positively on the correspondingly designed housing edge. For this purpose, a fastening element is provided, which can be, for example, a union nut, which presses the converter assembly with the sleeve encompassing the circuit carrier, which forms a sealing bead on the outer edge of the circuit carrier, against the edge of the housing.

An automatic fire detector designed in this way has the advantage that the tolerance-sensitive transducer components are arranged on one side, the components of the electrical circuit and any adjustment components are arranged on the opposite side of the subrack. There is a full car in a matching machine Functional adjustment possible. For this purpose, the side with the transducer elements is brought into a simulation chamber in which a defined fire size is simulated, while the automatic adjustment is carried out on the component side in a manner known per se.

A rigid intermediate layer can expediently be provided between the fastening element and the sealing bead, which surrounds the circuit carrier all around. This has the advantage that the force of the fastener, which is a terminal _- may or screw, is more evenly distributed, so that the electronics are sealed as well as possible against the surrounding atmosphere, and that the energy distribution of the circuit board is not damaged when jamming due .

The cover advantageously consists of a flexible, mechanically deformable, electrically non-conductive material, for example of a non-evaporation rubber. On the one hand, this has the advantage that the sealing edge or bead ensures a good seal. On the other hand, the flexible bottom of the shell, which runs at least partially parallel to the circuit carrier, compensates for barometric fluctuations in air pressure like a membrane. This reduces the leak rate at the edge of the seal because no negative pressure can arise inside the casing.

The circuit carrier can be formed by a circuit board with components arranged thereon or by a ceramic carrier with a hybrid layer circuit.

For contacting the electronics of the circuit carrier, contact pins with sharp conical tips arranged in the detector housing can pierce the sheath and form an electrically conductive connection with the contact surfaces of the circuit carrier. The cone of the contact pins gives the deformable sleeve material a good seal, which can be provided in a further development of the invention with an additional sealing ring on the contact pins in order to improve the seal if necessary. The contact pins are placed on a spring in the base, which they press permanently against the contact surface in the axial direction. The springs and the detector connection contacts can each be formed as one part.

Furthermore, the object is achieved by a method for manufacturing automatic fire detectors in that the converter assemblies are manufactured and compared in multiples, then separated, and a converter assembly is installed in each case in the detector housing, and in that a possibly additional converter element and the housing cover are placed on the housing or on the base.

This manufacturing process allows the transducer assembly to be manufactured automatically, which can advantageously be manufactured in multiples, that is to say, in use. Another advantage is that the converter assembly can also be adjusted in terms of use, and can be adjusted fully automatically and then separated. Then the respective converter module in the detector. housing used. For fully automatic function comparison, at least one converter assembly is advantageously brought into a simulation chamber. A defined fire parameter is simulated in the simulation chamber for the adjustment. The function of the detector is checked with the usual test equipment and the adjustment is carried out in a manner known per se. In the case of a circuit carrier, a matching element required in each case can be automatically determined on the basis of the function measurement and fed to the circuit carrier. The Adjustment element is automatically inserted into the circuit board and soldered. If the circuit carrier consists of a hybrid layer circuit, for example, the adjustment is also carried out automatically. In this case, the layer resistances can be compared in a manner customary with layer circuits today using a laser. In this way, one or more benefits can be compared in multiple ways. After these have been compared, the converter assemblies are removed from the simulation chambers and the next ones are placed in the simulation chambers. After that, the converter assemblies, which are manufactured and adjusted in multiples, are separated.

• die Fig. 1 einen optischen Rauchmelder im Schnitt,
• die Fig. 2 ein Detail gemäß Fig. 1,
• die Fig. 3 den Funktionsabgleich einer Wandler-Baugruppe und
• die Fig. 4 Schaltungsträger, die im Vielfach gefertigt sind.

The invention is explained in more detail using an exemplary embodiment, namely using an optical smoke detector as an example, without the inventive features being restricted to this type. Show

• 1 is an optical smoke detector in section,
• 2 shows a detail according to FIG. 1,
• 3 shows the function comparison of a converter assembly and
• 4 circuit carriers, which are manufactured in multiples.

. Fig. 1 shows an optical smoke detector based on the scattered light principle, shown in section. A circuit carrier 1, which can either be a printed circuit board type or a layer circuit on a ceramic carrier material, carries on one side the electronic components 2. This side looks at the detector base 26. On the other side of the circuit carrier 1 are in a very tolerant way Elements of the transducer arranged. In the exemplary embodiment, these are the light-emitting diode 3 and the photodiode 4. These are arranged such that the primary radiation 18 of the light-emitting diode 3 does not reach the receiving direction of the photodiode 4. In addition, apertures 17a are provided for this. To protect the electronic circuit from corrosion, the base side of the circuit carrier 1 is surrounded by a sheath 5. This sleeve 5 has on the outer edge la of the circuit carrier 1 a bead-like sealing edge 6 which surrounds the outer edge la of the circuit carrier 1. In the area of the contact surfaces 13 of the circuit carrier 1, the sleeve 5 lies flat on it. The contact pins 11 arranged in the base 26 via springs 15 each have a sharp, conical tip 11a according to FIG. 2. The sheath 5 is pierced by the tips 11a. Thus, the connection contacts 16 of the base are connected to the circuit carrier 1 via the contact surfaces 13. The cone shape of the tips 11a of the contact pins 11 ensure a good seal in the deformable sleeve material, which, if necessary, can be improved by sealing rings 12 arranged on the tips of the contact pins 11 (FIG. 2).

With a clamping or screwing element 7, e.g. a union nut, and possibly with the help of an additional stiff intermediate layer 8, the transducer assembly 14 is pressed onto the housing edge 9a of the detector housing 9. With the screw element 7, the circuit carrier 1 is pressed firmly against the housing edge 9a, so that the interior 5a of the converter assembly 14 is sealed against the surrounding atmosphere. The bottom 10 of the flexible, deformable casing 5, which can be made of rubber, for example, forms a flexible membrane that compensates for barometric fluctuations in air pressure.

The side of the circuit carrier 1 equipped with the elements of the physical-electrical converter, here light-emitting diode 3 and photodiode 4, faces the measuring chamber. In the case of the optical smoke detector, the measuring chamber is formed by the labyrinth 17, which shields the measuring chamber from extraneous light, but allows the smoke to enter. In this case, the orifices 17a also belong to the measuring chamber. The labyrinth 17 can be designed as a separate part. However, it can also be integrated in the housing cover (housing hood) 25, which is attached to the housing 9 of the detector.

FIG. 2 shows the automatic function comparison of a detector according to FIG. 1. In this case, the converter assembly 14, which is manufactured in multiples 19, is compared in use. The adjustment is carried out on the side of the electronic components 2 of the circuit carrier 1, which is indicated here with a laser 24 in the case of a layer circuit. Needle-shaped contact pins 22 contact the circuit carrier 1 via the contact surfaces 13. The transducer elements 3 and 4 are on the opposite side of the circuit carrier 1. They are introduced into a simulation chamber 21 which has panels 20 and a labyrinth similar to the detector according to FIG. 1. Smoke 23 of defined density is blown into the simulation chamber 21 through the opening on the side. With standard test equipment, the function of the detector. checked and the comparison made. As already mentioned above, even in the case of the printed circuit, an additional trimming element, for example a resistor, can be automatically fed to the circuit carrier 1 and soldered there, which is not shown here. The converter assemblies 14, which are manufactured in multiples, can thus be brought into the simulation chamber 21 one after the other and then compared.

FIG. ₄ shows circuit carrier 1, which has been manufactured in many cases, seen from the component side (2). The fire detector designed according to the invention on the one hand offers the advantage of fully automatic function comparison, so that a reliable function of the electronics is guaranteed. The converter modules (14) or circuit carrier 1 are separated after the adjustment. Then the sleeve 5 is pushed over it, then the transducer assembly is installed in the detector, as already explained above. On the other hand, the fire detector according to the invention has the advantage of replacing the converter assembly with another if the detector is defective or is being serviced. Today it is common practice, sometimes also prescribed, to clean fire detectors at certain intervals. Such cleaning requires a not inconsiderable effort. In such a case, it is more efficient for the fire detector according to the invention to discard the outer parts of the detector, for example the detector housing, the labyrinth, the casing, and possibly also the base, and only the electronic assembly with the transducer elements, ie the transducer assembly to continue using. Both cases can be used as simply as possible, because dismantling the detector is as easy as installing it.

Likewise, heat detectors with hot or cold conductors or ion detectors with radioactive sources can be designed, manufactured and calibrated as converter elements in accordance with the fire detector according to the invention.

Claims (41)

1. Automatic fire detector with a base (26), with a detector housing (9) in which a plurality of detector connection contacts (16) are arranged, with a detector circuit arrangement which has electronic components (2), with a physical-electrical converter (3, 4 ), with a measuring chamber (17, 17a) and a housing cover (25),
characterized in that on a flat circuit carrier (1) arranged in the detector housing (9) the electronic components (2) and several contact surfaces (13) on the base side and elements of the physical-electrical converter (3, 4, 17a) on the opposite side Are arranged side and together form a converter assembly (14), that the converter assembly (14) on the side of the electrical components (2) has a sealing, elastic sheath (5) which engages around the outer edge (la) of the circuit carrier (1) and forms a sealing bead (6), the sheath (5) rests on these in the area of the contact surfaces (13), that in the detector housing (9) biased in the axial direction (15) contact pins (11) with tips (lla) are arranged which penetrate the sheath (5) and form an electrical connection with the contact surfaces (13), and that the transducer assembly ( 14) on the outer edge (la) of the circuit carrier (1) is pressed non-positively with a fastening element (7) against the housing edge (9a). 2. Automatic fire detector according to claim 1,
characterized in that between the fastening element (7) and the outer edge (la) of the circuit carrier (1) or the sealing bead (6) Cover (5) a rigid intermediate layer (8) is arranged. 3. Automatic fire detector according to claims 1 or 2
characterized in that the sheath ( ₅ ) consists of an elastic, deformable, insulating material, the bottom (10) of the sheath (5) running at least partially parallel to the circuit carrier (1) forming a membrane. 4. Automatic fire detector according to one of the preceding claims,

characterized in that the circuit carrier (1) is formed by a printed circuit board. 5. Automatic fire detector according to one of the preceding claims, characterized in that the circuit carrier (1) and the electrical components (2) are formed by a hybrid layer circuit on a ceramic material. 6. Automatic fire detector according to one of the preceding claims,
characterized in that the contact pins (11) each have a sealing ring (12) in the region of the casing (5). 7. Automatic fire detector according to one of the preceding claims,
characterized in that the contact pins (11) are arranged in the detector housing (9) on electrically conductive springs (15) which are connected to the detector connection contacts (16) arranged in the base (26). 8. A method for manufacturing automatic fire detectors according to claim 1,
characterized in that the transducer assemblies (14) are manufactured and adjusted in multiples, then separated and one transducer assembly (14) is installed in the detector housing (9) and that an additional transducer element (17) and the Housing cover (25) are placed on the housing (9) or on the base (26). 9. The method according to claim 9,
characterized in that in many cases at least one converter assembly (14) is brought into a simulation chamber (21) in which a defined fire parameter (23) is simulated for the adjustment process. Reference symbol list 1 circuit carrier la outer edge of the circuit board 2 components 3 converter element (LED) 4 converter element (photodiode) 5 case 5a interior 6 sealing edge (bead). 7 fastening element (e.g. union nut) 8 stiff liner 9 detector housing 9a Detector housing edge 10 bottom of the cover (5) 11 contact pins lla tip of the contact pin 12 sealing ring 13 contact surface 14 converter assembly 15 (contact) spring 16 connection contact 17 labyrinth 17a orifice chamber 18 Primary training 19 Multiple 20 panels on the simulation chamber (21) 21 simulation chamber 22 needle-shaped contact pin for adjustment 23 fire parameter (e.g. smoke) 24 lasers (for function adjustment) 25 housing cover 26 detector base

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