DE10057113B4 - Energy supply arrangement for smoke and heat extraction systems with electric drives - Google Patents

Abstract

Energy supply arrangement for smoke and heat exhaust ventilation systems with electrical drives (20, 21), with at least one emergency power accumulator (9) that can be charged from a primary electrical energy source, with a switching device (14, 15), which is actuated by a controller and via which the drives (20, 21) and other consumers, such as the control, are fed from the emergency power accumulator (9) or in normal operation from another electrical energy source, and with a charge state monitoring device, characterized in that
that at least one main accumulator (8) is provided as another electrical energy source, the capacity of which is greater than that of the emergency power accumulator (9),
that the control comprises the state-of-charge monitoring device, which is connected to the main accumulator (8) and, when falling below a first minimum state of charge, activates a ventilation lock until a second larger minimum state of charge is exceeded, and which, when falling below a third minimum state of charge, which is lower than the first minimum state of charge , the switching device (14, 15) actuated so that the control and the drives (20, 21) from the emergency power accumulator ...

Description

The invention relates to an energy supply arrangement for smoke and heat exhaust systems with electric drives according to the preamble of claim 1.

In the case of smoke and heat exhaust systems - abbreviated SHE systems - can ventilation flaps by the electric drives from a closed position in an open ventilation position be moved and beyond for increased smoke and heat extraction, especially in the event of a fire, in an even wider open alarm position. For this purpose, the electric drives are controlled by a smoke and heat exhaust ventilation system controlled powered by electrical energy. Usually done the supply from an electrical network via a transformer and a rectifier connected downstream of this, which is a charging capacitor for smoothing applied. Furthermore, the regulation should be as extensive as possible a voltage regulator is provided from mains voltage fluctuations. This The power supply unit must be constructed in such a way that even short, high starting currents can connected - in usually connected in parallel - drives can be delivered. To A secure energy supply belongs to the state of the art at least one emergency power accumulator, which in the event of failure of the electrical Network takes over the energy supply of the electric drives, why a switch from mains operation to emergency power accumulator operation has to be done. The emergency power accumulator should last at least over a longer period, typically 72 hours, a quiescent current to power the controller, in particular the smoke exhaust system and ventilation control can deliver and then the electric drives with enough energy can supply so that the smoke flaps twice in the fully open alarm position and in between can move to the closed position. to The emergency power accumulator must be charged with a charging device, the usual a transformer, a rectifier with a charging capacitor, a Charging control and a charge controller includes. - So the technical Effort to the electrical drives of the smoke and heat exhaust system and the related one Smoke and heat exhaust systems and ventilation control reliable both during normal operation from the electrical network and at To supply power from the emergency power accumulator with power, considerably. This applies in particular to the desired regulation in network operation of mains voltage fluctuations as well as for the provision of high Starting currents.

In a known control and monitoring device for a smoke and heat exhaust system, a plurality of electronic assemblies or modules connected to a microprocessor are arranged in one housing ( DE 196 47 823 A1 ). A motherboard in the housing contains all connection elements and passive components for the basic functions of the system, in particular, among other things, a power supply for motors, a power supply for logic components, a switchover between mains and battery operation, connection elements for the mains connection, an R / W module , Signal relay, smoke detector, fire button, fan button and for two motor lines, connections for a transformer, a rectifier and accumulators. The transformer and the rectifier are mounted on a mounting plate and the batteries are placed on the bottom of the housing. A charging circuit of the accumulators has a simple charge controller with constant current and voltage limitation. A temperature compensation circuit is assigned to the charge controller, with the aim of ensuring that the charge controller always charges the accumulators in accordance with their capacity. - In general, the motors or motor lines are fed from the mains during normal operation and not from the accumulators, which are used exclusively to maintain emergency operation. It is therefore only a matter of emergency power accumulators. The energy supply arrangement, which is controlled with this control and monitoring device, therefore requires the high technical outlay set out at the beginning.

The latter also applies to another known generic power supply arrangement in which the power supply to the motor drives is decentralized, in that power supply units such as transformers, rechargeable batteries or the like are arranged in close proximity to the drives ( DE 195 07 407 A1 ). A motor control unit, which is used to supply power to 4 SHEV drives, for example, can have a rechargeable battery with the associated charging and monitoring device. Operating states and malfunctions such as power failure and battery failure are recorded in the engine control unit, which are transmitted to a control center and shown there. The control center has its own power supply with a transformer, which also feeds fire pushbuttons, for example, but is not used to power the SHEV drives.

The present invention has for its object to improve an energy supply arrangement for smoke and heat exhaust systems with electrical drives of the type mentioned in that the technical effort for the provision of electrical energy with which the electrical drives and the control including the smoke and Heat extraction and ventilation control are applied at simultaneous increase in reliability is reduced.

This task is accomplished through an energy supply arrangement solved with the features specified in claim 1.

The solution is based on the principle that not only an emergency power accumulator for safe operation in the event of failure of the primary electrical energy source, typically an electrical network, is provided, but that also for normal Operating case at least one accumulator, referred to as the main accumulator, is provided, its capacity larger than that of the emergency power accumulator, and that the energy output of the main power accumulator and of the emergency power accumulator not only depends on the availability of the primary Energy source, but also at least depending on the state of charge of the main accumulator is controlled.

So even if the primary electrical Energy source, in particular an electrical network is undisturbed, in this normal case the energy supply comes from the main accumulator, the short-term high starting currents of the electric drives can provide the required nominal currents for smoke and heat exhaust ventilation systems many drives connected in parallel without the use of complex Three-phase power supplies can deliver and the tension for the electric drives largely without complex control circuits keeps constant. The main accumulator therefore has a buffer function and acts as Voltage control element. About that In addition, the energy supply can also be used if the primary energy source fails the smoke and heat exhaust system and a quiescent current supply, in particular of the control from the Main accumulator take place as long as it does not fall below a specified one Limit, namely the third charge state minimum value, is discharged. Accordingly enough an emergency power accumulator of a relatively small capacity. To the functions performed by the power supply arrangement are essential the activation of a so-called ventilation lock when a first charge state minimum value of the main accumulator is undershot. This first minimum state of charge lies over the final discharge voltage, which in particular according to claim 4, the third state of charge minimum value is. If the ventilation lock is activated, the main current accumulator can still provide the necessary quiescent current deliver and the electrical energy for further travel commands electric drives available until the third charge level falls below becomes. - The above mentioned ventilation lock means that electric drives, the smoke and heat flaps in the ventilation position move, first automatic be stopped and then in the closed position move in which they remain until the ventilation lock is released again becomes.

According to claim 2, the control equipped with a charging energy failure monitoring device, which a charge energy failure for the main accumulator and monitors the emergency power accumulator and reports. So that an actuation the switching device from the position in which the control and the drives are fed from the emergency power accumulator into the Position in which the supply from the main accumulator takes place, be ordered when a charging power failure has ended. Then you can the lifting of the ventilation block, which is activated when the minimum charge level falls below the first is permitted when the charging power failure has ended.

The charge status monitoring device can according to claim 3 simply as a voltage monitoring device be trained.

With outputs of the switching device, to which the control and drives for energy supply connected to the main accumulator or the emergency power accumulator are can according to claim 5 other electrical consumers of the smoke and heat exhaust system and / or related external power units. A radio interface, a bus interface, a smoke and heat exhaust system interface as well as a ventilation interface, the latter for one Include wiring with quiescent current lines.

Under the terms main accumulator and emergency power accumulator is not only a single accumulator understood, but it can also Groups of accumulators to a main accumulator respectively Emergency power accumulator can be summarized.

The principle according to the invention can be in connection with various primary electrical energy sources use advantageously; is the most common the provision of the primary electrical energy through an electrical network, from which according to claim 6 over a DC voltage generator and a charge controller each the main accumulator and the emergency power accumulator can be powered. The DC voltage generator is a power supply or power supply unit with a mains transformer with rectifier and Charging capacitor. Such DC voltage generators are also used other variants of the invention used.

In particular, according to claim 7 the main accumulator and the emergency power accumulator each via one separate DC voltage generator and a separate charge controller be supplied with electrical energy from the electrical network. The the latter division of energy supply following the electrical network can ensure the security of the power supply arrangement increase and the selection of lower performing Enable components of the DC voltage generator.

In the course of an environmentally friendly electri cal energy generation can advantageously serve as the primary electrical energy source, a solar energy source which, in the variant according to claim 8, is connected via a solar energy source switch in its first switching position via a separate charge controller to the main accumulator and the emergency power accumulator. In the second switch position of the solar source switch, on the other hand, the solar energy source is connected via an inverter to an electrical network for the recovery of excess solar energy. The solar energy source changeover switch can be switched over by the charge state monitoring device of the control and is switched over to the second switch position when the main accumulator and the emergency power accumulator have reached their end-of-charge voltages, ie should no longer be charged.

In extension of the above Variant can according to claim 9 advantageously two solar energy sources as an electrical energy source are used, with one of the two solar energy sources via one associated Solar energy source switch in its first switch position with the main accumulator or with or the emergency power accumulator in connection can be brought. In another, namely the second switch position the solar energy switch is over a common inverter feeds energy back into the electrical grid, those for charging the main accumulator and / or the emergency power accumulator not required becomes. The energy recovery is enhanced in this extended variant by the fact that it does not require that both the main accumulator and the emergency power accumulator is fully charged, but it becomes the charging energy fed back each for there is no need to charge the main accumulator or the emergency power accumulator is.

In the variant according to claim 10 can charge the main accumulator and the emergency power accumulator reliable also take place when the solar energy, for example because the weather, is not sufficient. In this case, only in the alternative accessed the electrical grid for charging by using an energy source switch is operated in a corresponding switching position, the operation depending on of the voltage generated by the solar energy source. Excess, not solar energy required to charge the main accumulator and the emergency power accumulator can turn over an inverter can be fed back into the electrical grid. Between that electrical network and the charge controller is as a DC voltage generator a power supply or power supply inserted.

An advantageous combination of two solar energy sources with auxiliary provision of the electrical Network as the primary Energy source is specified in claim 11. The main accumulator and the emergency power accumulator are charged via separate charge controllers, which are primarily fed from solar energy sources and only if the energy supply from the solar energy sources is too low, either via a common DC voltage source - mains transformer with rectifier and charging capacitor - or over two separate DC voltage sources can be loaded. A recovery of excess solar energy takes place via a common inverter in the electrical grid as soon as either the main accumulator or the emergency power accumulator Final charge voltage has reached.

The invention is illustrated below a drawing with 5 figures explained, in the simplified Circuit arrangements of the power supply arrangement shown are, namely:

1 A basic version with an electrical network as the primary electrical energy source for charging the main accumulator and the emergency power accumulator via a common direct current source,

2 an arrangement according to the first variant 1 , but with two separate DC voltage generators for charging the main accumulator and the emergency power accumulator,

3 a second variant with a solar energy source for charging the main accumulator and the emergency power accumulator,

4 a third variant with two solar energy sources, one of which is connected to charge the main accumulator and one to charge the emergency power accumulator, and

5 as a fourth variant, a solar energy source which, in addition to charging the main accumulator and the emergency power accumulator, is used for energy recovery in an electrical network.

In the basic version according to 1 there is an electrical network 1 via a mains transformer 2 and a rectifier 3 with charging capacitor 4 with inputs of a power supply control not designated 5 connected, which is shown only as a block. At outputs of the power supply control 5 is via a charge controller each 6 respectively 7 a main accumulator 8th or an emergency power accumulator 9 connected. Lines lead from these 10 and 11 back to the power supply control, namely to a separate charge status monitoring device contained therein for the main accumulator and the emergency power accumulator. The power supply control 5 also contains at least one charge energy failure monitoring device that reports a charge energy failure for the main accumulator and the emergency power accumulator.

Furthermore, the power supply control 5 outputs 12 and 13 for controlling one of changeover relays 14 . 15 existing switching device and an output 16 to operate a Ventilation lock on.

Via the changeover relay 14 . 15 , which are drawn in the normal position, the direct current energy required to control and actuate a smoke and heat exhaust system is alternatively the main accumulator 8th or the emergency power accumulator 9 taken. This direct current energy is transmitted through one of the lines 17 . 18 into a smoke and heat exhaust system and ventilation control 19 fed in, which is shown as a block and is abbreviated as SHEV and ventilation control. At unidentified outputs of the SHE and ventilation control 19 the electrical drives to be actuated by this are connected, for example the electrical drives 20 and 21 , which can also represent a group of drives.

The SHE and ventilation control 19 can control commands from an external periphery 22 via a ventilation interface 23 , an RWA interface 24 received, the connection to the periphery can be made via conventional quiescent current lines. Furthermore are in the SHEV and ventilation control 19 a bus interface 25 and a radio interface 26 provided, via which SHEV control commands, ventilation control commands and feedback can also be transmitted.

With the described basic energy supply design, the method according to the invention is carried out after the energy supply of the SHE and ventilation control system by means of a quiescent current and, upon appropriate commands, the energy supply of the electric drives 20 . 21 over the lines 17 . 18 normally from the main accumulator 8th takes place opposite the emergency power accumulator 9 has a higher capacity, the main accumulator 8th and the emergency power accumulator 9 also as a buffer during a charging process from the electrical network 1 via the DC voltage source with the transformer 2 , the rectifier 3 and the charging capacitor 4 serve. Controlled by the energy supply control 5 are the changeover relays 14 . 15 in emergency operation in their in 1 position shown. The drives are used for daily ventilation 20 . 21 however only from the main accumulator 8th fed if a corresponding ventilation command in the RWA and ventilation control 19 comes in, for what the changeover relay 14 . 15 is switched. The drives 20 . 21 can move into the ventilation position and remain until the main accumulator 8th falls below a first charge state minimum value, which is determined by the charge state monitoring device in the energy supply control 5 is recorded. When this condition is recorded and reported, the ventilation lock is activated via the output 16 the energy supply control 5 in SHE and ventilation control 19 activated. A notification of the failure of the charging energy from the rectifier 3 and charging capacitor 4 is also used in energy supply control 5 reported. After reinstalling the main battery charge 8th The ventilation lock remains activated until the main accumulator 8th is sufficiently charged and exceeds a second minimum charge state value, which in turn by the charge monitoring device in the power supply control 5 is recorded. After activating the ventilation lock, it can be removed from the main accumulator 8th still quiescent current via the changeover relay 14 . 15 in the SHEV and ventilation control 19 be fed in, but in the same way, but not shown, also a supply of the energy supply control 5 can be done.

The SHE and ventilation control as well as the energy supply control are also referred to collectively as controls.

Only when a third minimum charge state value of the main accumulator occurs due to the quiescent current draw in the absence of charging 8th is fallen below, which is preferably equal to the final discharge voltage, is determined by detecting this state of charge with the state of charge monitoring device in the power supply control 5 a changeover of the changeover relay 14 . 15 triggered so that now the emergency power accumulator 9 relatively small capacity the quiescent power supply of the control, in particular the SHEV and ventilation control 19 can take over 72 hours and enough energy to control all drives, including the drives 20 . 21 when RWA commands occur, especially with a prescribed command sequence, which first moves to the alarm position within 15 minutes, then to the closed position and finally back to the alarm position after the charging energy has failed.

As soon as the charging energy is available again, it is switched back to the energy withdrawal from the main accumulator. If the SHE is triggered again after charging is resumed, the electric drives can 20 . 21 first again via the through the energy supply control 5 actuated changeover relay 14 . 15 from the main accumulator 8th be charged, whereby its cargo reserves can be used. The ventilation lock is then released when the main accumulator 8th reaches a second minimum state of charge value which is greater than the first minimum state of charge value and in any case greater than the third minimum state of charge value at the end of discharge voltage.

For the variants of the above basic version described below, the same components of the energy supply arrangements shown have the same reference numerals as the basic version according to 1 Mistake.

In the first variant of the energy supply arrangement according to 2 serves the described DC power source, consisting of the to the electrical network 1 connected transformer 2 with downstream rectifier 3 and charging capacitor 4 , only for charging the main accumulator 8th via its charge controller 6 and a modified power supply control 27 ,

The modified power supply control 27 has another entrance 28 on, the charging energy only for the emergency power accumulator 9 records, which in turn via the associated charge controller 7 can be loaded. The entrance 28 is also from the electrical network 1 , but via a separate DC source with a transformer 29 , a rectifier 30 and a charging capacitor 31 applied.

Apart from the separate charging option for the main accumulator 8th and the emergency power accumulator 9 the function of the first variant is the same as that of the basic version.

The second variant according to 3 differs from the basic version in that the charging energy of the main accumulator 8th and the emergency power accumulator 9 not from the electrical network 1 - as the primary electrical energy source - is taken, but from a solar energy source 32 which is a solar cell array. The solar energy source 32 can via a solar energy switch 33 , a changeover relay, with inputs 34 . 35 a modified power supply control 36 get connected. Between the entrance 35 and an exit 37 the modified power supply control 36 there is a connection so that an inverter 38 for energy recovery in the network 1 - from the solar energy source 32 via the solar energy switch 33 and the entrance 35 - can be applied. In the position shown, the solar energy switch is with the input 34 for charging the main accumulator 8th and the emergency power accumulator 9 connected. A switch to the input 35 occurs when the main accumulator 8th and the emergency power accumulator 9 have reached their end-of-charge voltages, after which the solar energy no longer required as charging energy enters the grid 1 is fed back.

The third variant of the energy supply arrangement after 4 differs from the second variant according to 3 in that the solar energy source 32 only for charging the emergency power accumulator 9 via the associated charge controller 7 serves, whereas for charging the main accumulator 8th via its charge controller 6 a second source of solar energy 32 ' , also a solar cell arrangement, is provided. This is via a separate second solar energy source switch 39 , also a changeover relay, optionally with an input 40 or 41 a modified power supply control 42 in connection. outputs 43 and 44 the modified power supply control are available internally with the inputs 35 respectively 41 connected and lead to the inverter 38 , The inverter 38 is in turn for energy recovery in the network 1 intended. In the in 4 shown position of the solar energy source switch 33 and 39 become the emergency power accumulator 9 from the solar energy source 32 and the main accumulator 8th from the solar energy source 32 ' charged independently of each other until their final charge voltage is reached. When the final charge voltage is reached, the solar energy switch 33 respectively 39 individually moved to the other switch position, in which a connection between the solar energy source 32 or the solar energy source 32 ' to the inverter 38 is produced and solar energy not required for charging into the network 1' is fed back.

The fourth variant of the energy supply arrangement after 5 differs from the second variant according to 3 in that the main accumulator 8th and the emergency power accumulator 9 primarily their charging energy from the solar energy source 32 can obtain from this, however, if the energy supply is insufficient, alternatively from the electrical network 1' as the primary electrical energy source. An energy source switch serves this purpose 45 , the solar energy source in the preferred switching position shown 32 with the charge controllers 6 and 7 of the main accumulator 8th and the emergency power accumulator 9 connects, in the other switching position, however, with the direct current source, consisting of the transformer 2 , the rectifier 3 and the charging capacitor 4 , with the transformer connected to the network 1' is connected as the primary electrical energy source.

A recovery of solar energy that is used to charge the main accumulator 8th and the emergency power accumulator 9 is not needed in the network 1' is about a switching element 49 ' an energy source switch and a further modified energy supply control 46 , namely their entrance 47 and exit 48 via the inverter 38 possible. The excess solar energy is fed back when in the modified power supply control 46 it is detected that the main accumulator 8th as well as the emergency power accumulator 9 have reached their final charge voltage. In this case, another switching element 49 opened, which belongs to the energy source switch.

Claims (11)

Energy supply arrangement for smoke and heat exhaust ventilation systems with electrical drives ( 20 . 21 ), with at least one emergency power accumulator ( 9 ), which can be charged from a primary electrical energy source, with a switching device ( 14 . 15 ), which is actuated by a control and via which the drives ( 20 . 21 ) and other consumers such as the control from the emergency power accumulator ( 9 ) or fed from another electrical energy source in normal operation, and With a state-of-charge monitoring device, characterized in that at least one main accumulator ( 8th ) is provided, the capacity of which is greater than that of the emergency power accumulator ( 9 ) is that the controller includes the state-of-charge monitoring device which is connected to the main accumulator ( 8th ) is connected and, when falling below a first minimum charge state value, activates a ventilation lock until a second larger minimum charge state value is exceeded, and which, when falling below a third minimum charge state value, which is lower than the first minimum charge state value, the switching device ( 14 . 15 ) actuated so that the control and the drives ( 20 . 21 ) from the emergency power accumulator ( 9 ) are fed. Energy supply arrangement according to claim 1, characterized in that the control comprises a charging energy failure monitoring device which a charging energy failure for the main accumulator ( 8th ) and the emergency power accumulator ( 9 ) reports which actuation of the switching device ( 14 . 15 ) from the position in which the control and the drives ( 20 . 21 ) for smoke and heat vent activation from the emergency power accumulator ( 9 ) are fed into the position in which the supply from the main accumulator ( 8th ) takes place, commands when a charging power failure has ended, and which permits a subsequent lifting of the ventilation lock, which is activated when the charge level falls below the first minimum charge level, when the charging power failure has ended. Energy supply arrangement according to claims 1 and 2, characterized in that the charge state monitoring device as a voltage monitoring device is trained. Energy supply arrangement according to claim 3, characterized through, a dimensioning of the voltage monitoring device that the third minimum state of charge the final discharge voltage of the Main accumulator is. Energy supply arrangement according to one or more of the preceding claims, characterized in that with outputs of the switching device ( 14 . 15 ) to which the control and drives ( 20 . 21 ) are connected, other electrical consumers of a smoke and heat exhaust system and / or associated external power units are connected. Energy supply arrangement according to one or more of the preceding claims, characterized in that an electrical network ( 1 ), which is via a DC voltage generator ( 2 . 3 . 4 ) and one charge controller each ( 6 . 7 ) with the main accumulator ( 8th ) and the emergency power accumulator ( 9 ) is connected. Energy supply arrangement according to one or more of claims 1-5, characterized in that an electrical network ( 1 ), which uses a DC voltage generator ( 2 . 3 . 4 ; 29 . 30 . 31 ) and one charge controller each ( 6 . 7 ) on the one hand with the main accumulator ( 8th ) and on the other hand with the emergency power accumulator ( 9 ) is connected. Energy supply arrangement according to one of claims 1-5, characterized in that the primary electrical energy source is a solar energy source ( 32 ) which is via a solar energy source switch ( 33 ) in its first switching position via a charge controller ( 6 . 7 ) with the main accumulator ( 8th ) and the emergency power accumulator ( 9 ) is connected and in its second switching position via an inverter ( 38 ) with an electrical network ( 1' ) Excess solar energy is fed back into this, and that the solar energy source switch ( 33 ) can be switched into the second switching position by the charge state monitoring device of the control when the main accumulator ( 8th ) and the emergency power accumulator ( 9 ) have reached their final charge voltages. Energy supply arrangement according to one of claims 1-5, characterized in that the primary electrical energy source two solar energy sources ( 32 . 32 ' ), of which one each has a solar energy source switch ( 33 . 39 ) in its first switching position via a charge controller ( 6 . 7 ) with the main accumulator ( 8th ) or with the emergency power accumulator ( 9 ) can be connected and in its second switching position via a common inverter ( 38 ) with an electrical network ( 1' ) Excess solar energy is fed back into this, and that each of the solar energy source switch is independent of the other by a charge state monitoring device that the main accumulator ( 8th ) or the emergency power accumulator ( 9 ) is monitored, can be switched to the second switching position when the end-of-charge voltage of the main accumulator or the emergency power accumulator is reached. Energy supply arrangement according to claim 8, characterized in that instead of the solar energy source ( 32 ) alternatively the electrical network ( 1' ) serves as the primary energy source into which excess solar energy is switched via the solar energy source switch ( 49 . 49 ' ) and the inverter ( 38 ) is regenerative, and that the solar energy source ( 32 ) or the electrical network ( 1' ) about an Ener source switch ( 45 ) and the respective charge controller ( 6 . 7 ) with the main accumulator ( 8th ) and the emergency power accumulator ( 9 ) is connectable. Energy supply arrangement according to claim 9, characterized characterized that instead of one of the two solar energy sources alternatively, the electrical network serves as the primary energy source, in which excess solar energy is at least one of the solar energy source switch is regenerative, and that each one of the two solar energy sources or the electrical network via one energy source switch each and over the corresponding one Charge controller with the main accumulator or the emergency power accumulator is connectable.