DE1588617B1 - ELECTRICAL MONITORING CIRCUIT, IN PARTICULAR FOR MONITORING THE CONTROL CIRCUIT OF AN ALARM DEVICE THAT CAN BE TRIPPED BY THE EFFECT OF SMOKE OR OTHER PARTICULAR SUBSTANCES - Google Patents

Description

and optical alarm devices or fire doors. In the case of such electrical monitoring circuits assigned to a display device, it is important that that their operational readiness can be checked with the least possible effort, not so failure of the monitoring circuit itself makes it impossible to generate an alarm in a critical case.

The invention is therefore based on the object of creating an electrical monitoring circuit, in which using the principle of closed-circuit current switching with the simplest possible means The alarm can also be triggered if, apart from the presence of smoke in the display device, for example the light source burns out or a partial failure of the energy supply occurs.

To solve this problem, the invention is based on an electrical monitoring circuit of known type described at the outset and consists in the fact that a single one to actuate warning and / or security means, such as acoustic and optical alarm devices or fire doors, certain at Influencing a first operating state by a current flowing only or predominantly in one direction and assuming a second operating state when influenced by an alternating current electrical switching device is provided that the control circuit fed by an alternating current source for the switching device to this in series, but connected in parallel with each other Has current paths each containing a diode and a switching element in series therewith, that the diodes are connected in antiparallel and the one switching element when the control circuit is ready for operation is switched on, while the other switching element fulfills the control function of the control circuit, for example, in the presence of smoke, can be switched on.

The invention has the decisive advantage that a single switching device is capable of is to take three precisely defined switching states, the first state by being de-energized the system indicates the operational failure, the middle state an excitation state for the non-alarming state Normal case means that the monitoring circuit assumes during the third state is able to cause such a circuit that again with security an alarm is triggered full energy supply takes place.

According to an advantageous embodiment of the invention, the switching device is from one Relay formed with make and break contacts, to whose excitation coil a capacitance as an impedance shunt is connected in parallel. The switching elements in the current paths to the switching device are photocells.

Further advantageous refinements or developments of the invention are the subject matter of the subclaims and laid down in these.

In the following, the structure and mode of operation of an exemplary embodiment of the Invention explained in more detail. It shows

Fig. 1 is a horizontal section through a smoke indicator at the height of the light beam path,

Fig. 2 is a vertical section along line 2-2 in Fig. 1,

F i g. 3 shows the circuit diagram of the electrical monitoring circuit in a schematic representation.

With reference to FIG. 1 and 2 show the smoke indicator device designated in its entirety by 10 Housing 12, a light source 14 located outside the housing and a photoelectric one protruding into the housing Element 16, with the system in constant readiness for operation, as will be described below is located.

The display device 10 of the exemplary embodiment is particularly suitable for use in conjunction with a smoke alarm system. For this purpose, the housing 12 consists of a standing cylindrical Wall part 18 with two end caps 20 and 22 above and below, through which a darkened inside Chamber 24 is created. The end caps 20, 22 overlap the wall part 18 with one another directed flanges 26 and 28 which encompass the wall part 18 with a radial spacing. At the front ends of the wall part 18 are set by a number of spacers 30 directed obliquely outward on, which create a friction fit against the inner surfaces of the flanges 26, 28 and in this way the Hold the end caps in place. The flanges 26 and 28 form together with the spacers 30 peripheral Passages at each end of the wall part 18 through which smoke from the surrounding atmosphere can penetrate into the chamber. To direct the light beam emitted by the light source 14 and to steer, a focusing tube 32 extends through the housing wall 11 on one side thereof, and a light receiving tube 34 is in the housing wall 18 on the opposite side to that Focusing tube 32 arranged in alignment. In the focusing tube 32 there is a convex lens 36 from such a focal length that light emitted by the light source 14 in a converging beam at Bottom of the light receiving tube 34 is bundled so that the light beam at the bottom of the tube 34 a has minimal cross-section and the smallest possible amount of scattered light on any other Part of the inner surface of the case falls.

Between the light receiving tube 34 and the focusing tube 32 extends through the housing wall part 18, an indicator tube 38 directed substantially perpendicular to the axis of the other two tubes is. The display tube 38 holds the photoelectric element 16 and a converging lens 40 between it element 16 and chamber 24 to limit the field of view of the element. the Converging lens 40 has a focal length such that the image of element 16 is reduced to the smallest possible area is focused on the opposite side of the housing wall part 18 and the focusing cone of the display element 16 is directed transversely to the focusing cone of the light source 14, so that the photoelectric element can only capture the middle part of the light beam and its field of view a central portion of the opposite wall part 18 is limited. The element 16 consequently cannot grasp the peripheral openings on the ceiling and on the floor of the wall part 18; also almost no other light can reach the element 16, with the exception of the light that appears in the focusing cone of the converging lens 40.

To further ensure that only a minimal amount of internal stray light reaches element 16, is the end 42 of the indicator tube on the side adjacent to the light receiving tube 34 forward.

5 6

towards the focusing cone of the light beam. In the illustrated embodiment, the alarm device A can also be lengthened so that a screen against stray light is provided by a separate energy source, for example a battery B, which is fed from the inner surface of the focusing tube 32. The free end of the display are, while the door locking device D is fed by tube 38 from this foremost point according to 5 of the energy source E , beveled backwards at such an angle that the inner surface of the display tube 38 is not to ensure trouble-free operation which makes it necessary that the alarm device can then also detect the inner surface of the focusing tube 32. responds and the fire doors are also closed Light on the locking device for the fire door ineffective receiving tube located opening half of the display is. For this purpose, the alarm device, tube with a beveled screen 44, as just mentioned, is covered with its own energy source. Ie 2? via the normally closed contact X 1 of a Gleichin the embodiment shown sits 15 relay R1 is connected, which is opened when the housing, the light 12 on a support plate 46, and energizes relay coil, and the fixing device D source 14 is on this support plate in The system for the fire door is attached to the energy source E via the focusing tube 32 and connected to an electrical power source of an operating current X 2 of the same relay. The arrangement of the bound light source outside the housing 12 creates a 20 is closed when the relay coil R 1 is energized. Under normal operating conditions, the single-optical inspection facility for its operational readiness, ie when there is no smoke in the shop and facilitates its replacement. housing is available, the relay coil Rl of the element 16 can be designed in any way, so alternating current source E via a photocell PC 2 switched in series and a rectifier Di only responds to a change in the light intensity, ie it can a photocell or a light 25 excited. Also be in series with relay coil R1 via sensitive resistor. A particularly suitable cell of this type is the AC source £ are a third photocell, works with cadmium sulfide, PC 3 and a diode D 2 connected, the polarity of which is based on an increase in the light beam intensity compared to the diode D 1 for a further down with a decrease in its electrical power Resistance refined purpose is reversed, so the value reacts to the photo cell. In the embodiment shown, PC 2 is connected in anti-parallel. For example, a control The photocell PC2 is connected in relation to the circuit which is arranged on the cell light source 14 so that when the resistor is switched on it receives a light beam under normal operating conditions and is set without smoke, so that a certain resistance consequently drops to such a low value of the cell resistance one to the circuit 35 that a sufficiently large direct current semi-connected alarm device triggers. If now wave over the diode D 1 and the relay coil to flie-smoke penetrates into the housing and in the light ßen is able to reach the closed-circuit contact X 1 in the open beam, light from the smoke gas particles will hold position. In the event of a disturbance in the light in the light beam source 14 detected by the element or in the energy source E, however, the section is reflected or deflected towards this, whereupon the relay de-energizes, the closed-circuit contact X 1 closes, and the resistance value of the cell is reduced the alarm device is activated while the alarm is activated and the alarm circuit is activated. shunt current contact X 2 opens and the locking device

In Fig. 3 is the alarm and control circuit for direction D for the fire door is de-energized. Use in conjunction with the display device In order to trigger an alarm when smoke particles are present in FIGS. 1 and 2, namely when the housing 12 is switched on, the element of the alarm is switched. The circuit according to FIG. 3, 16 is connected to the alternating current source via a fixed predetermined resistance Kl , however, which can be fed by an alternating current source E, and is used to control an alarm device E connected, with a glow lamp 50 partung ^ t, if the photoelectric Element 16 is connected to the resistor Kl . If there is illuminated suspended matter within the display 50, there is no space in the housing 12, the device is detected, and furthermore, for triggering a resistance of the element 16, so high that the chip-locking device D, which closes a voltage at the resistor K 1 does not cause the ignition of the fire door or the like. Fire doors are sufficient for 50 glow tubes. If, however, the smoke usually penetrate into the housing 12 with weights or springs in particles and are biased in the closing direction and are passed through a beam of light, they are perceived to be open by the element 16 locking means, for example by means of a lock Resistance drops. If it is held, which has a part which decreases the resistance to a certain value in such a way that the lock is loosened, the voltage across the resistance is reached and the door closes by itself. The means K1 a sufficient height to ignite the glow lamp 50 for keeping the door open can also electrically 60. The photocell PC 3, which is arranged in such a way, has an actuatable pawl, which is normally opened to the light of the glow lamp 50 and is able to take the lock when it is released, receives light and is released so that the door closes able. In tend. The current can flow through the diode in the drawing, the device D represents an electrical D 2 and the photocell PC 3, but only when the latch is actuated, which in the energized state a 65 of the opposite half-wave opposite the Jeni fire door or a similar device ( not shown, with which the current via the photocell PC 2 is kept open and when the excitation is lost, the diode D 1 is able to flow. This has allowed the door to close automatically. Consequence that on the relay coil R 1 and the capacitance

did F now the full wave of the alternating voltage appears. The capacitance F acts as a low impedance shunt for the alternating voltage, whereby the current flow through the relay coil R 1 is reduced to a value at which the relay drops out and the closed-circuit contact closes with the result of the alarm being triggered.

In the illustrated embodiment, the alarm is automatically terminated when the smoke development has ceased. This happens because the resistance of the element 16, which is now increasing again, extinguishes the glow lamp 50, whereby the resistance of the photocell P 3 also increases and current only reaches the relay coil R 1 and the capacitance F connected in parallel in one direction. This stops the effect of the capacitance F as an impedance shunt, the relay coil is energized again, the closed-circuit contact Zl opens and the closed-circuit contact X 2 closes, so that the input is interrupted and the locking device for the fire door is again supplied with energy. In some cases it may be desirable to keep the alarm circuit containing the closed circuit X1 closed once smoke has been detected. This can then easily be achieved in a known manner by a self-holding contact for the relay coil R 1.

Although a photocell PC 2 is switched on in the illustrated embodiment in the current path that only passes rectified current half-waves to the relay coil, in some cases a relay with an excitation coil connected in series with the light source 14 can also be provided instead. A closed current contact of this relay is then in series with the diode D 1 and is closed as long as the light source 14 is on.

The relay R 1, the capacitance F and the two current paths containing the diodes D 1 and D 2 together form a monitoring circuit which is kept in a first operating state by current half-waves flowing in only one direction, while the current half-waves flowing in both directions and thus a full one Alternating current resulting current half-waves put the monitoring circuit in a second operating state. In the illustrated embodiment, the excitation of a first photocell keeps the monitoring circuit in the first operating state, and the excitation of this and a further photocell puts the circuit in the second operating state.

1 sheet of drawings

209 523/59

Claims (6)

1 2 Claims: The invention relates to an electrical monitoring circuit, in particular for monitoring the 1. Electrical monitoring circuit, in particular control circuit of a by the action of special to monitor the control circuit smoke or other suspended matter triggered by the action of smoke or other alarm device with a light source and suspended matter triggerable alarm device containing a photoelectric element display with a light source and a photoelectric device, in which a display device containing penetrated suspended matter, in which scattered light affects the electrical resistance of the particle penetrated by the element, with a direct current element, with a direct current element, which indicates the operational reliability of scattered light , with a fail-safe closed circuit,
denomination of the display device, with DC-Electrical monitoring circuits under Verström operated quiescent current circuit, because the turn of a DC-operated quiescent characterized by that a single, current circuit to control the operational safety for the operation of warning and / or fuse 15 are for example from the German Patent means, such as acoustic and optical alarm 928 088 known. This is a rubern (A) or fire door (D) specific signal system monitored by with current after the loop influence by an only or predominantly in the system, which can be used for a fire alarm system but is a first load does not give the fire alarm directly, but rather the operating state and when influenced by a 20 in which the fire alarm is triggered by other means, in the case of alternating current, a second operating state, for example by a telephone call to the central operator's electrical switching device (Rl, len or given by the central office to external locations X 1, X 2) it is provided that the will of a change. In such a system, it is important that the self-powered control circuit for the line transmitting the fire alarm does not break, switching device (Rl, Xl, Xl) to this in 25 or that in the event of breakage, corresponding series of circuit dimensions, but measures connected in parallel, are taken which nevertheless has an over current path, each of which allows a diode (P1, averaging of the signal. For this purpose D 2) and a series of switching elements to determine the operational safety of the device (PCI, PC 3), that the diodes lay relay arranged in the loop under constant (Dl, Dl) connected anti-parallel and the one 30 according to direct current influence (closed-circuit current monitoring switching element (PCI) with operational control principle); If the loop breaks, this currentless circuit is switched on, while the other then the relays drop out and take certain switching elements (PC 3) when the control circuits are fulfilled, which then ensure the transmission of a sifunction of the control circuit, for example gnals. Information about an automatic in the presence of smoke, can be switched on. 35 Alarms are not made. 2. Monitoring circuit according to claim 1, furthermore, for example, from Fig. 6 of the deutd characterized in that the Schalteinrich- see Auslegeschrift 1 081 804 a circuit with device (Rl, Xl, Xl) can be taken from a relay with Ar- connected fire alarms, beits - and break contacts is formed, to which these are ionization chambers, excitation coil (R 1) a capacitance (F) as an impedance 40 which can close a circuit and is connected in parallel to this danzshunt. Way to energize a relay, which 3. Monitoring circuit according to claim 1 in turn a pulse generator with an alternating and / or 2, characterized in that the power source connects so that periodically due to switching elements in the current paths photocells of a further direct current source in a closed (PC 2, PC 3) are. 45 voltage peaks appear in the circuit 4. Monitoring circuit according to one or more of the claims 1 to 3, characterized in this case a glow tube, to operate an optical display device. This indicates that the photocell (PC 2) of one arrangement can not be taken directly from the light radiation of the monitoring device information about an operating current path.
Light source (14) of the display device of the alarm 50 alarm devices for triggering signals device is exposed. exposure to smoke or other 5. Monitoring circuit for one or suspended solids generally use a diminutive of claims 1 to 4, characterized by kelte chamber, through which one of a light indicates, that the photocell (PC 3) of the light beam emitted by the other source is directed. A forum Current path the light beam of a glow 55 toelectrical receiving element, for example a lamp (15) is exposed, which at the affect photocell, is arranged so that it is only the to detect the electrical resistance of the photo-central section of the light beam Element (16) in the display device (10) like and opposite a direct irradiation through the alarm device, for example, is shielded by a light source. If there is a levitation effect of smoke, can be switched on. 60 gas containing substances, especially smoke, into the 6. Monitoring circuit according to claim 5, housing of the display device characterized by the fact that the photoelectric openings and enters the light beam, then element (16) in series with a potentiometer cause the suspended matter contained in the gas (K 1) to the alternating current source (E) switched on a reflection or deflection of the light in Richist and that parallel to the potentiometer the 65 direction on the photoelectric element. The glow lamp (50) is switched on as a result. caused change in the resistance of the photoelectric element then becomes external to actuation _____ Warning and / or safety devices, such as acoustic ones