DE29519021U1 - Circuit arrangement for a zone heating - Google Patents

Description

Circuit arrangement for a zone heating system

The invention relates to a circuit arrangement for zone heating with a flash cooking stage, mass hotplates and radiant heat sources in hob recesses.

Such solutions for zone heating with rapid boiling stages are known in that after boiling and switching to the larger heating zone, a heating component that is housed in the outer heating circuit is connected upstream of an inner heating component and thus, when both heating zones are in operation, the inner heating power is reduced due to the series resistor. The disadvantage of such solutions is that the associated mechanical energy regulators cannot regulate such power connections with sufficient sensitivity, and in addition, excessive power in the inner heating zone area would have to be clocked, whereby the equalization of the heat energy to the effective heating zone for the relevant cooking pot is not ensured. The object of the invention is therefore to create a circuit arrangement for a zone heating system with rapid boiling stage that avoids these disadvantages.

ZRP95P637

The arrangement according to the invention for solving this problem is characterized in that the circuit arrangement for a zone heating is designed for at least three different switchable heating outputs for heat equalization in as many operating stages as possible, whereby two smaller inner heating zones (1, 2) can be selected as flash cooking stages and a third heating zone can be operated in combination with them, which effectively expands the heating circuit circumference and allows two heating output stages as a large heating zone.

A further advantageous solution to the problem is provided by the fact that the circuit arrangement for zone heating consists of current paths that contain at least four different heating outputs and two cooking zone sizes as a range of switching variants. Other advantageous embodiments of the invention are contained in the subclaims of the protection claims. An embodiment according to the invention is described in more detail below with reference to the drawing. It shows:

Fig. 1 shows a circuit arrangement according to the invention, Fig. 2 shows a corresponding embodiment of a radiator.

According to Fig. 1, heating elements 1, 2 and 3, switches 4, 5, 6 and 7, a temperature limiter 8, a button or sensor 9, and the current paths 10, 11 and 12 can be seen. According to Fig. 2, the heating elements can be removed in a practical design variant as heating elements 1, 2 and 3.

ZRP95P637

If we consider the circuit arrangement according to Fig. 1, then the following circuit variants can be implemented:

Switch 4 is closed, switch 5 and zone switch 9 are open.

Under these conditions, the current path from a phase L to the neutral conductor N, as shown in Fig. 1, can be seen as current path 11 when switch 7 is switched on, and the heating elements 1, 2 are connected in series, while heating element 3 is idle. This means that for the switching variant consisting of the series connection of the heating elements 1, 2, approx. 950 watts of heating power can be provided. By connecting the heating elements 1 and 2 in series, a lower power is distributed over larger areas of the heating elements, so that the heating power is evened out. This switching variant corresponds to a moderate boiling. If the current path 11 is interrupted by the switch 4, but switch 5 is closed, then when the switch 7, 8 is closed, the current path 10 is closed and a current flows through the heating element 2. In this case, the current does not flow through the heating elements 1, 3. In this case, approximately 1200 watts of heating power are provided, enabling a stronger boiling, which, as can be seen from Fig. 2, takes place on the middle tracks of the heating element. In previous energy regulator stages, this heating power level was switched on in switch position 9, while the heating power level for 950 watts, concerning current path 11, could be set in heating power levels 1 to 9. The powers can be clocked if the

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ZRP95P637

Power clock β is activated. This generally occurs according to the program or sensor-controlled. If the switch for the outer heating zone 9 is switched on using a button or sensor and switch 4 is closed, then heating current flows through the current paths 11, 12 and a heating output of approx. 2100 watts is achieved. This output is achieved because the heating output inside is 950 watts and the heating output in the outer circuit of 1150 watts is added to this. This switching variant represents a balanced heating variant with switched-on zone heating outside, whereby the inner heating zone 1 in particular with the following heating zone 2 causes the heating output to be balanced. The principle is that with a lower heating output for the inner heating circuits and a constant heating output of the switchable zone heating outside as a result of the designed heating output levels in conjunction with the power clock 6, an energetically optimized continued cooking is possible depending on the pot size. The maximum power is taken from the heating power circuit according to Fig. 1 when switch 5 is closed in energy regulator position 9 and zone switch 9 is also closed, thus forming current paths 10 and 12. In the example given, this switching variant delivers a heating power of approx. 2350 watts, which is made up of the power generated by heating power body 2 plus the power generated by heating power body 3. This switching variant leads to rapid boiling for pots that cover at least heating power zone 3. In this case, after a necessary boiling time, circuit 10 would be opened and circuit 11 closed, so that 2100 W are available for continued cooking, which can be specifically timed for the pot and cooking process using power timer 6.

ZRP95P637

The solution according to the invention fulfils the task and advantageously forms four possible power zones. These power zones are distributed in two switching variants to the inner heating power zones 1, 2 and
the total heating output zone, consisting of the heating output zones
1, 2 and 3. For both the inner and the overall performance zone it is advantageous
circuitry provides that higher power rates for boiling
are available and continued cooking, which may be timed, is available for both the inner and outer heating power levels.

Claims (5)

ZRP95P637 PROTECTION CLAIM 1. Circuit arrangement for zone heating with a flash cooking stage, relating to mass hotplates and radiant heat sources in hob recesses, characterized in that the circuit arrangement for a zone heating is designed for at least three different switchable heating outputs for heat equalization in as many operating stages as possible, whereby two inner smaller heating zones (1, 2) can be selected as flash cooking stages and in combination with this a third heating zone (3) which fictitiously extends the heating circuit circumference and allows two heating output levels as a large heating zone (1, 2, 3). 2. Circuit arrangement according to claim 1, characterized in that the circuit arrangement consists of the current paths (10, 11, 12) which contain at least four different heating outputs and two cooking zone sizes as a switching variant scope. 3. Circuit arrangement according to claim 1, 2, characterized in that for the switching variant consisting of the series connection of the heating power body (1) and heating power body (2), approximately 950 W of heating power can be provided. 4. Circuit arrangement according to claim 1, 2, characterized in that for the switching variant which switches on the heating power body (2) via the current path (10), approximately 1200 W of heating power can be provided. - 2 ZRP95P637 5. Circuit arrangement according to claim 1, 2, characterized in that for the switching variant which switches on the heating power bodies (1, 2, 3) via the current paths (11, 12), approximately 2100 W of heating power can be provided. β. Circuit arrangement according to claim 1, 2, characterized in that for the switching variant which switches on the heating power bodies (2, 3) via the current paths (10, 12), approximately 2350 W of heating power can be provided.