EP0003124A1 - Device for the ventilation of rooms - Google Patents

Abstract

In a ventilation device for rooms, the air openings are to be optionally opened and closed by means of an electric drive (1). In this connection, the drive can on the one hand be switched on via a bistable flip flop (26) assigned to a supply main branch (10', 11'), but can on the other hand be switched off automatically (8, 9) on reaching the opening or closing position respectively by a disconnector (10 or 11) situated in the respective supply main branch (10', 11'). At the same time it is envisaged that the flip flop (26) operates the main switch (27, 28) and is arranged in or on the ventilation device. An infrared or ultrasound remote control (23), consisting of a transmitter (24) and a receiver (25), serves to operate the flip flop (26), its receiver (25) being situated in the vicinity, but advantageously likewise in or on the ventilation device. By means of this design, a ventilation device can be installed without problems; it can, however, be individually operated from any place in the room to be ventilated. At the same time, it is particularly advantageous that, as transmitter (24) for the infrared or ultrasound remote control, a device can be used directly as is known for functional control of television, radio or phono apparatus. A definable transmission channel of the same can at the same time be tuned into for operation of the ventilation device. <IMAGE>

Description

b) Technical field

The invention relates to a ventilation device for rooms, the air passage openings of which can be optionally opened and closed by means of an electric drive, and in which the drive can be switched on via a bistable toggle switch assigned to a power line branch and, on the other hand, in each case when the opening or closing position is reached by one in the respective power line branch horizontal disconnect circuit can be switched off automatically.

c) State of the art.

In the ventilation device according to patent application P 27 20 739.2, the mains cable for the electric drive is assigned a manually operable main switch with a changeover contact having two stable rest positions and / or a changeover contact controlled by a relay. The switching state of the relay is determined by an electrochemical or electronic gas sensor via an amplifier or voltage multiplier. The gas sensor responds when a certain gas concentration in the interior is exceeded and influences the relay via the amplifier or voltage multiplier in such a way that it changes its changeover contact from the stable rest position to the likewise stable working position, whereupon the drive actuates in the opening direction for the air passage openings becomes.

The isolating circuits provided in each power line branch according to patent application P 27 20 739.2 consist of microswitches that can be alternately opened and closed via a cam disc that can be adjusted by the drive, in such a way that, on the one hand, the drive effective in the opening direction when the opening position is reached and, on the other hand, the one effective in the closing direction Drive is disconnected from the mains when the closed position is reached.

Patent application P 27 19 144.2 also proposed a ventilation device for rooms which has a manually operable main switch with an alternating contact having two stable positions of rest and is also designed such that the sound waves are kept away from the interior of the room when noise peaks occur in the area. For this purpose, a sound sensor, e.g. B. uses a microphone, and a circuit arrangement which can be triggered by this, and which, when the air passage openings or channels are de-energized when the airborne sound occurs, spontaneously initially in the sense of closing the ventilation openings or channels and then delaying again in the sense of opening the Ventilation openings or ducts are energized. Here, the time switch actuates a relay with a changeover contact, which in its idle state applies voltage to a microswitch for the drive that is only open when the air passage openings or channels are open, but in its switching state it also applies a microswitch for the drive that is only open when the air passage openings or channels are closed Tension connects.

While in certain cases the ventilation function according to patent application P 27 20 739.2 automatically operates, i.e. without a human decision, the ventilation device according to patent application P 27 19 144.2 also, in certain cases, opens and closes controlled independently, i.e. without a human decision.

In both cases, on the other hand, for the voluntary function control of the ventilation device, it is necessary to manually actuate a main switch in the mains cable for the electric drive and equipped with a changeover contact. This main switch must, of course, be installed at an easily accessible location in the room to be ventilated at all times, which means that a more or less complex cable installation is always necessary. The effort to be carried out for this is particularly great if a room is equipped with several ventilation devices which should be controllable independently of one another.

Special difficulties also arise if it becomes necessary for some reason to move the installation location for the main switch.

d) Description of the invention

The purpose of the invention is to avoid these disadvantages. Therefore, the object of the invention is to provide a ventilation device for rooms of the generic type which can be installed without problems and yet can be actuated individually from any point in the room to be ventilated.

According to the invention, this goal is achieved in a simple manner achieved that the bistable flip-flop forms the main switch, as well as provided in or on the ventilation device and can be operated by an infrared or ultrasonic remote control consisting of a transmitter and a receiver, the receiver at least in the vicinity, but preferably also in or on the Ventilation device sits.

The transmitter can be a battery-powered infrared or ultrasound transmitter, which is located in a handy housing and can be operated using a tip contact.

According to the invention, the flip-flop can be formed by an alternating contact relay with two stable rest positions, which is connected to the infrared or ultrasound receiver via an amplifier.

However, it has proven to be particularly favorable if, according to the invention, the flip-flop consists of a flip-flop, the two outputs of which are connected to the control electrode of different thyristors located in the two power line branches.

If the ventilation device with a forced fan driven by an electric motor, e.g. B. a fan, it has proven itself according to a further feature of the invention, the electric motor of the forced ventilator assigned to the open position of the air passage openings To connect the mains cable branch for the drive to the mains. In order that the forced ventilation only starts when the air passage openings are completely clear, it has also proven useful to form the isolating circuit located in the network line branch assigned to the opening position of the air passage openings by means of an alternating contact. which alternately connects the drive and the electric motor to this branch of the power line.

It can prove to be particularly advantageous if, according to the invention, the receiver can be tuned to a predetermined transmission channel of a known, multi-channel red light or ultrasound transmitter. Such multi-channel red light or ultrasound transmitters are in fact already widely used today as control devices for television, radio and phono devices and are usually also equipped with a larger number of transmission channels than are absolutely necessary for the control of the television, radio and phono devices become. At least one of the transmission channels of these known control devices can then easily be used for function control of the ventilation device.

e) Description of the drawing figures

• Fig. 1 shows a block diagram of a basic embodiment of the invention. Tax system in association with the electric drive for the closure member of a ventilation device.
• Fig. 2 shows a modified embodiment of the control system according to the invention for driving the closure member of a ventilation device.
• Fig. 3 discloses the assignment of an electric motor-driven forced ventilation to the ventilation device in a first embodiment.
• Fig. 4 shows the assignment of an electric motor-driven forced ventilation to the ventilation device in a second embodiment.

f) ways of carrying out the invention

1 to 4 of the drawing, an electric motor is indicated as an electric drive 1 for moving the closure member for the air passage openings or channels of a ventilation device. This drive 1 is constructed as an AC asynchronous motor, preferably as a geared motor, and is designed, for example, for a voltage of 220 volts with a power consumption of 0.025 kW.

On the shaft 2 of the drive 1 sits, for example, a crank disk (not shown), the crank pin of which Opening and closing process for the air passage openings or ducts of the ventilation device causes and for this purpose acts on the closure member assigned to them.

Furthermore, a cam 8 with a control cam 9 is wedged onto the shaft 2, which cooperates with two microswitches 10 and 11, which can be mounted, for example, on the housing of the drive 1.

The arrangement of the microswitches 10 and 11 relative to one another and to the cam disk 8 is such that the microswitch 10 above the control cam 9 is only opened at the moment when the closure member of the ventilation device has reached its open position. However, as soon as the closure member begins to move back into the closed position, it is closed again. On the other hand, the microswitch 11 is open and it is closed after the closure member has reached its open position. It then remains closed until the closure member reaches its closed position again and is then opened again by the control cam 9 of the cam disk 8.

1, the two microswitches 10 and 11 can be alternately connected to the network via a switch contact 12. If the switch contact 12 connects the closed microswitch 10 to the network via the power line branch 10 ', then the closure member of the ventilation device is switched off via the drive its closed position is moved in the opening direction until the microswitch 10 is opened above the control cam 9 of the cam disk 8. Although the microswitch 11 is already closed, there is no consequence as long as the switch contact 12 remains connected to the microswitch 10 via the power line branch 10 '.

However, if the switching contact 12 closes the closed microswitch 11 via the power line branch 11 'to the power supply, the drive 1 receives power again and moves the closure element of the ventilation device back from the open position into its closed position. If the latter is reached, the microswitch 11 opens while the microswitch 10 is already closed.

The switch contact 12 is designed as a changeover contact and is actuated by a polarized relay 13 with two rest positions. In the one rest position of the relay 13, the switch contact 12 is connected via the power line branch 11 'to the microswitch 11, which is open in the closed position of the closure member of the ventilation device. In the other rest position of the relay 13, on the other hand, the switch contact 12 is connected via the power line branch 10 'to the microswitch 10, which is closed until the closure member has reached the closed position.

The respective switching current for the relay 13 provides a Ver stronger 15, which in turn is influenced by an infrared or ultrasonic remote control (23).

The infrared or ultrasonic remote control consists of a transmitter 24 and a receiver 25, the receiver 25 being fixed in place, for example in or on the ventilation device, while the transmitter 24 can be movable.

Each transmission pulse from the transmitter 24 influences the receiver 25 in this way. that this gives a surge to the relay 13 through the amplifier 15. With each current surge it is achieved that the relay 13 tilts from the position of rest it has just assumed into the other position of rest and thereby switches the switching contact 12.

After each changeover of the switch contact 12, the electric drive receives 1 current so that it either moves the closure member of the ventilation device in the shut-off position into the open position or the closure member of the ventilation device located in the open position into the locked position. When the shut-off position is reached, it is stopped by opening the microswitch 10, but when the release position is reached, it is stopped by opening the microswitch 11.

The embodiment of a control system for ventilation before 2 differs from that of FIG. 1 essentially only in that the amplifier 15 operates on a bistable multivibrator 26, in particular a flip-flop.

One output 26 ′ of the flip-flop works on the control electrode of a thyristor 27, while the other output 26 ″ is connected to the control electrode of a thyristor 28.

The thyristor 27 is installed in the power line branch 11 'and the thyristor 28 in the power line branch 10'.

Each transmission pulse given by the transmitter 24 to the receiver 25 of the infrared or ultrasonic remote control 23 causes the flip-flop 26 to tip over from the one to the other switching state via the amplifier 15. As a result, the outputs 26 'and 26 "of the flip-flop 26 are always live. Accordingly, the two thyristors 27 and 28 are alternately made permeable to the mains current, that is, this is alternately via the mains line branch 11' to the microswitch 11 or via the power line branch 10 'led to the microswitch 10.

Each of the thyristors 27 and 28 remains permeable as long as voltage is present at its control electrode on the one hand and the associated power line branch 11 'or 10 'is closed. Accordingly, the thyristor 27 remains permeable to the mains current only as long as the output 26 'of the flip-flop 26 is excited and the microswitch 11 is closed; on the other hand, the thyristor 28 remains permeable only as long as the output 26 "of the flip-flop is excited and the microswitch 10 is kept closed. This ensures that each transmission pulse from the infrared or ultrasonic remote control 23 causes the ventilation device to be switched from the just taken functional position is triggered in the other functional position.

Fig. 3 of the drawing shows the control system based on Fig. 1 for a ventilation device which, in addition to an electric drive 1 for moving the closure member for the air passage openings or channels, also influences a forced ventilator 30 driven by an electric motor 29, for example a fan.

Here, the electric motor 29 of the forced cooling fan 30 can be connected directly to the network via the line branch 10 ′ after the relay 13 has placed the switch contact 12 on the line branch 10 ′.

As indicated by the dashed lines, there is the possibility of connecting the electric motor 29 of the forced ventilation fan 30 to the mains immediately after the switching contact 12 has been set on the mains line branch 10 'for fan operation, so that the forced ventilator 30 already starts up while the opening process for the closure member of the ventilation device is still taking place.

A solid line, however, indicates an arrangement in which the electric motor 29 can only start after the closure member of the ventilation device has reached its final opening position. In the latter case, the microswitch 10 must be designed as a changeover contact switch, which connects the electric motor 29 to the network only at the moment when the drive 1 for the closure member is disconnected from the network.

FIG. 4 again shows a control system comparable to FIG. 3, which, however, in contrast to FIG. 3, is based on the control system according to FIG. 2.

In this case, since the function control for the drive 1 of the closure member of the ventilation device is effected via the thyristors 27 and 28, which can be influenced by the flip-flop 26, the electric motor 29 for the forced ventilator 30 can also be energized via the mains line branch 10 '. when the microswitch 10 has interrupted the mains connection to the drive 1.

For this purpose, it is only necessary to equip the microswitch 10 with a changeover contact that connects the power line branches 10 'to the electric motor 29 after it has previously separated it from the drive 1.

Since the voltage at the output 26 "of the flip-flop 26 is still present at the control electrode of the thyristor 28 until the next transmission pulse occurs, even if the microswitch 10 has disconnected the drive 1 from the mains, the latter is immediately used again for the mains current permeable when the changeover contact of the microswitch 10 closes the circuit for the electric motor 29.

The circuit for the electric motor 29 of the forced ventilation fan 30 now remains closed until the flip-flop 26 tilts due to a further transmission pulse from the transmitter 24. The output 26 "of the same then becomes de-energized, while its previously de-energized output 26 'receives voltage. Now the drive for the closure element of the ventilation device becomes active again via the mains line branch 11" and the closed microswitch 11: to move the closure element from its open position into the Lock position to put. The resulting rotations of the cam disc 8 thus cause a changeover of the changeover contact on the microswitch 10. Since the circuit for the electric motor 29 is first interrupted at a time during which there is no control voltage at the control electrode of the thyristor 28, this becomes again for the Mains current impermeable before the changeover contact of the microswitch 10 has established a connection to the drive 1. The electric motor 29 of the forced ventilator 30 thus comes to a standstill while the drive 1 closes the closure member brings the ventilation device into its closed position, in which the microswitch 11 is opened via the cam disk 8 '. This then interrupts the current flow to the drive 1, although control voltage is still present at the output 26 'of the flip-flop 26 and thus at the control electrode of the thyristor 27.

Finally, it should also be mentioned that as a transmitter 24 for the infrared or ultrasonic remote control 23 a device can be used without further ado, as is known for television, radio or phono apparatuses for function control. Such control devices operating on the basis of red light or ultrasound namely have a larger number of transmission channels, which are generally not all required for the function control of the apparatus in question. The receiver assigned to the ventilation device can therefore easily be matched to a free transmission channel of this control device, so that this is also useful for the function control of the ventilation device.

g) The commercial area of use

The control systems described above can be used wherever it is important to achieve individual function control of ventilation devices without the need to lay any control lines.

^h ) Reference symbol overview

• 1 electric drive
• 2 wave
• 8 cam disc
• 9 control cams
• 10 microswitches
• 10 'power line branch
• 11 microswitches
• 11 'Power line branch
• 12 switching contact
• 13 relays
• 15 amplifiers
• 23 Infrared or ultrasonic remote control
• 24 transmitters
• 25 recipients
• 26 bistable flip-flop, in particular flip-flop
• 26 'output of the flip-flop
• 26 "output of the flip-flop
• 27 thyristor
• 28 thyristor
• 29 electric motor
• 30 forced fans

Claims (6)

1. Ventilation device for rooms, the air passage openings of which can optionally be opened and closed by means of an electric drive and in which the drive is assigned on the one hand via a branching of a mains line. bistable flip-flops can be switched on and, on the other hand, can be automatically switched off each time the open or closed position is reached by means of a disconnect circuit located in the respective power line branch,
characterized,
that the toggle switch (13 or 26) actuates the main switch (12 or 27, 28) and is provided in or on the ventilation device and by an infrared or ultrasonic remote control consisting of a transmitter (24) and a receiver (25) ( 23) can be actuated, the receiver (25) of which is located at least in the vicinity, but preferably also in or on the ventilation device. 2. Ventilation device according to claim 1,
characterized,
that the flip-flop (12, 13) is formed by a changeover contact relay with two stable rest positions, which is connected to the infrared or ultrasonic receiver (25) via an amplifier (15). 3. Ventilation device according to claim 1,
characterized,
that the flip-flop (26) consists of a flip-flop, the two outputs (26 "and 26") of which are connected to the control electrode of various thyristors (27 and 28) located in the two line branches (11 'and 10'). 4. Ventilation device according to claims 1 to 3 with a fan driven by an electric motor, for. B. a fan,
characterized,
that the electric motor (29) of the forced ventilation fan (30) can be connected to the network (12, 10; FIGS. 3 and 28, 10; FIG. 4) via the network line branching (10 ') assigned to the opening position of the air passage openings ). 5. Ventilation device according to claim 4, characterized in
that the isolating circuit (10) located in a power line branch (10 ') consists of an alternating contact which alternately connects the drive (1) and the electric motor (29) to this power line branch (10'). 6. Ventilation device according to claims 1 to 5, characterized in
that the receiver (25) can be tuned or tuned to a predetermined transmission channel of a known, multi-channel red light or ultrasound transmitter (24).

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