DE4041798C2 - Extractor hood control - Google Patents

Description

The invention relates to a method for control an extractor hood for one underneath Hob with one located in the area of the hob Signal generator and one arranged in the extractor hood Sensor and an evaluation circuit, which by a manual control can be bypassed and / or which can also bypass the manual control, as well as a Hob and an extractor hood to perform this Procedure.

For herds equipped with time programming Tet, the extractor is through such a process hood automatically even when the operator is absent switched on when time programming requires it.

An extractor hood is known from DE 32 45 302 C2, where one sensor is on a sensor in the hob Signal generator responds. This sensor is through the rest heat indicator or the operating light indicator controlled. With such a method, it can be considered a disadvantage be that through the constant transmission of an output signals of the signal generator in the hob a high Electricity is consumed. It can also be a steady exit signal no additional information about the number the switched on radiator of the hob. So only the decision is - extractor hood on / off - possible. A control of the fan speed depending on the operating state of the hob can not.

The invention has for its object a method to develop an extractor hood control which the power consumption of the transmitter is significantly lower than with conventional methods.

According to the invention this object is achieved by solved the features of the main claim.

The invention is also based on the object of a Cooker hood and hob to develop with who can carry out this procedure.

This object is achieved by the in the An sayings 3 and 5 specified features solved. Appropriate Further developments and refinements result from the subclaims.

The achievable with the training according to the invention Advantages are that to send a pulsed most output signal a much lower average DC as for the transmission of a continuous signal is needed. This makes building a very price cheap transmitter possible. So can the pulse generator e.g. B. be built without a transformer and he only requires small assemblies. It's a simple installation guaranteed in a cooktop and with a purchase of a cooker without an extractor hood is minimal Additional costs. Another advantage is that one of the general operating condition of the hob dependent control of the fan speed of the extractor hood hood is possible.

An embodiment of the invention is in the drawing nations is shown purely schematically and is shown below explained in more detail. Show it:  

Fig. 1 is a perspective view of a recessed in a countertop cooking zone,

Fig. 2 is an illustration of the signal path diagram in a block,

Fig. 3 shows the time-dependent representation of a pulse sequence for controlling the extractor hood.

Fig. 1 shows a hob ( 2 ) embedded in a worktop ( 1 ). It has an infrared transmitter ( 3 ) on the back and controls ( 4 ) on the side for switching on the individual hotplates ( 5 ). Above the hob ( 2 ) there is an extractor hood ( 6 ) which has a photoelectronic sensor element ( 7 ) on its underside as a receiver. In addition, the extractor hood ( 6 ) has switches ( 8 ) on the front for manual speed control.

In Fig. 2 is a block diagram of the signal path between the hob (2) and hood (6) is shown. Control lines ( 9 , 10 ) lead from the control elements ( 4 ) of the hob ( 2 ) to a pulse generator ( 11 ) and a logic circuit ( 12 ) which follows the pulse generator. These supply the infrared transmitter ( 3 ) with a time-variable signal current I _{led, which} depends on the number of hotplates switched on. The signal emitted by the infrared transmitter is received by the photo-electronic sensor element ( 7 ) in the extractor hood ( 6 ) and passed on to an evaluation circuit ( 13 ). The evaluation circuit controls the speed of the fan motor ( 14 ) depending on the received signal.

The timing of the signal emitted by the pulse generator ( 11 ) is shown in FIG. 3. The output current I _led has a first pulse duration t ₁ and has the period T1. This periodic output signal is only transmitted in fixed, discrete time periods t2 with a period T2. The average output direct current thus results

I _ledav = I _max . (t ₁ × t ₂ ) / (T ₁ × T ₂ )

Let t ₁ / T _{1 be} a fixed quantity, whereas t ₂ / T ₂ can be selected depending on the operating state of the hotplate.

Choosing t ₁ / T ₁ to 0.1 and t ₂ / T ₂ to 0.1 to 0.3 results in a current consumption of 0.01 to 0.03 times the _maximum absorption current I _max . When dimensioning this current, it must be ensured that the response threshold of the receiver is surely exceeded.

Claims (5)

1. A method for controlling an extractor hood for an underneath cooktop with a signal transmitter located in the area of the cooktop and a sensor element arranged in the extractor hood as well as an evaluation control which can be bridged by a manual control and / or which can also bypass the manual control, characterized in that the signal transmitter in the area of the cooktop ( 2 ) emits a pulsed output signal when at least one radiator ( 5 ) is switched on, which outputs the fan motor ( 14 ) in the extractor hood ( 6 ) via the sensor element ( 7 ) and the evaluation circuit ( 13 ) starts up. 2. The method according to claim 1, characterized in that the pulse generator ( 11 ) is a logic circuit ( 12 ) which sends the pulsed signal only in discrete, depending on the operating state of the hob ( 2 ) gene dependent time intervals which correspond to a superimposed timing. 3. Hob for performing the method according to one of claims 1 or 2, characterized in that a pulse generator for supplying a signal generator is arranged in the hob ( 2 ). 4. cooktop ( 2 ) according to claim 3, characterized in that the mean taken from the network generator ( 11 ) mean direct current has a maximum strength of 0.7 mA. 5. Extractor hood with a receiving device and an evaluation circuit, which can be bridged by a manual control and / or which can also bypass the manual control, for performing the method according to one of claims 1 or 2, characterized in that the evaluation circuit ( 13 ) controls the fan speed depending on the signal sent by the transmitter in the hob ( 2 ).