DE19813421A1 - Jitter-minimising drive method for at least one heating element of mains powered heating device - Google Patents

Abstract

The method involves using electronic switches for at least one heating element. The power per period is controlled via the size of pulse packets consisting of a number of mains half waves. Pulse packets of equal polarity are arranged in sequence in equal numbers at the start and end of the period depending on the power. Further half waves of a different polarity are arranged in sequence in association with a pulse packet above 50 per cent depending on a further power. The polarities of the mains half waves are cyclically interchanged after each period.

Description

The invention relates to a control method according to the Genus of the preamble of claim 1 and the Claim 3.

In known heating devices is one to one Heating resistor in series switch one sensitive influencing of the temperature of the dispensed Warm air depending on an adjustable setpoint possible. For this purpose, the switch is used in a known manner controlled by a pulse packet controller. The ones from The heating power emitted by the heating resistor is pulsed activation of the switch, generally one Triac, set in the voltage zero crossing. Since that Any ratio of pulse lengths to pulse pauses can be selected, the heating output in this way between zero and the maximum by the radiator feasible performance can be varied almost arbitrarily.

At the voltage feedback on power grids are in recently increased requirements (flicker standard EN 61000-3-3). For example, one for Hand-held hair dryers or drying hoods are used too switching power of normally <1000 W According to regulations, such large switching intervals are required that the time constants of fast radiator systems are clear exceeded and thus excessive temperature Flowing air fluctuations occur. The allowed Switching times are only used for hand hair dryers and Drying hoods significantly lower nominal power acceptably small. A solution according to DE 40 23 250 A1 goes  the way, the radiator in two or more Split low-power resistors, and a rapid successive, simultaneous switching of the To prevent partial resistances in a suitable manner. This However, the process is technically / constructively complex and only limited for retrofitting in existing devices suitable.

The object of the present invention is therefore a to create a flicker-minimized triggering process that simple measures keeping an undivided Radiator allowed, but optionally also in systems with divided heating strands can be used.

This task is performed according to the distinctive part of the Claim 1 and claim 3 solved. Beneficial Further training results from the subclaims.

The invention is based on several exemplary embodiments described in more detail.

It shows:

Fig. 1 is a block diagram of a power control;

Fig. 2 is a block diagram of a temperature control;

FIG. 3 shows different pulse packets of a first embodiment;

Fig. 4 different pulse packets of a second embodiment, and

Fig. 5-7 two successive pulse packets each.

Fig. 1 shows a basic block diagram of a flicker-minimized power control by means of electronic switches for at least one heating element of a network-operated heating device, wherein a microcontroller detects positive and negative half-waves by means of a zero-crossing detection of the network half-waves and controls a circuit breaker with corresponding half-wave pulse packets. A specific power can be specified via a power setting device.

A basic block diagram of a temperature-dependent (regulated) power control is shown in FIG. 2, wherein a temperature setpoint is specified, which is compared by the microcontroller using a temperature sensor that is thermally coupled to the heating element and controls the circuit breaker with appropriate pulse packets.

In FIG. 3, 11-14 is illustrated by the seven pulse packets 2, 3, described in detail 21, the power control method in a first embodiment. The power per period T is controlled by the size of pulse packets 1-21 . The pulse packets 1-21 consist of a series of network half-waves A, B, C, the half-waves A, B of a first polarity in the same number being arranged in succession at the beginning and end of the period T, depending on the power. Over 50% power control the pulse packet are assigned to 12-21 in response to a further power more half-wave C of a second polarity in succession, the polarities of the mains half-cycles A, B, C after each period T are changed cyclically. Cyclical swapping has the advantage that the network is loaded with few DC components. For reasons of illustration, a period T corresponding to 20 full network waves (= 40 network half-waves) has been selected here (as also according to FIG. 4). In practice, a period T corresponding to 50 full network waves (= 50 Hz = 1 s) should be common. After the selected period T, 21 power levels from 0% to 100% are possible, as the following table shows.

The half-waves C can - as shown - in the middle as well be arranged at the beginning or end of the period T.

., The power control method, 21 'described in more detail in a second embodiment - in Figure 4 is the example of seven pulse packets 2', 3 ', 11' 14 '. The power per period T is controlled via the size of pulse packets 1 '- 21 '. The pulse packets 1 '- 21 ' consist of a series of network half-waves D, E, the half-waves D of a first polarity at the beginning of the period T and the half-waves E of a second polarity at the end of the period T being arranged in an equal number depending on the power . Again, of the 21 pulse packets 1 '- 21 ' (corresponding to 21 power levels) only the pulse packets 2 ', 3 ', 11 '- 14 ' and 21 'are shown. The corresponding 21 power levels could be controlled manually by means of a corresponding step switch or the like via a microcontroller, or a temperature control according to FIG. 2 could optionally be provided. After the selected period T, the 21 power levels (0% to 100%) are built up in 5% power steps, which is shown in the following table.

From an output of 55%, the half-waves D, E - depending on the additional power level - change into corresponding full waves. The resulting DC component is incorporated in its maximum permissible value in the EN 61000-3-2 standard and may be a maximum of approximately 1160 W with pure half-wave control. To further relieve the load on the power network, it is proposed to cyclically exchange the polarity of the pulse packets at intervals that are not harmful to the flicker standard, in order to reduce the average component ( FIG. 6). Furthermore, the DC load on contacts is reduced, among other things. As measurements show, with good control quality and a fast, undivided radiator system, more than 1000 W can be achieved with this method, while observing the limit values of the standard EN 6100-3-2, a short-term power Pst (Power short time / measuring time = 10 minutes) to values well below the limit value be lowered by 1.

In FIG. 5, two successive periods T ₁ and T _2, identical with two pulse packets 13 ', 13' (Fig. 4), where this occurs when change of period, a full-wave jump X, which in a further development of the invention according to FIG. 6 it is avoided (as is the duration of half-waves of the same polarity) that the polarities of the half-waves D ', E' are cyclically exchanged after each period T ₁ (T ₁ , T ₂ etc.).

In FIG. 7, two pulse packets 13, 13 (Fig. 3) are shown, wherein the polarities of the half waves A, B, C are of the period T exchanged cyclically ₁ (T ₂ = A ', B', C '/ T ₁ = A, B, C), whereby the DC component is minimized.

For actuation beyond a heating element, it is proposed that a first heating element with the first and a second heating element with the second polarity of half-waves A, B, C or D, E be applied, or that a first heating element be cyclically applied with the first period T ₁ and a second heating element with the second period T _{2 is} applied. In a further development, the power process is integrated in a temperature control, and a heat treatment device for head hair can be provided as the heating device.

Claims (8)

1. Flicker-minimized power control method by means of electronic switches for at least one heating element of a mains-operated heating device, characterized in that

• - that the power per period (T) is controlled via the size of pulse packets ( 1-21 ),
• - That the pulse packets ( 1-21 ) consist of a series of network half-waves (A, B, C), the half-waves (A, B) of a first polarity in equal number depending on the power at the beginning and end of the period (T ) are arranged in succession,
• - That the pulse packet ( 12-21 ) over 50% power control depending on a further power further half-waves (C) of a second polarity are assigned in succession, and
• - That the polarities of the network half-waves (A, B, C) are exchanged cyclically after each period (T).

2. The method according to claim 1, characterized characterized in that the half-waves (C) the second polarity essentially in the middle of the Period (T) can be arranged. 3. Flicker-minimized power control method by means of electronic switches for at least one heating element of a mains-operated heating device, characterized in that

• - That the power per period (T) is controlled via the size of pulse packets ( 1 '- 21 '), and
• - That the pulse packets ( 1 '- 21 ') consist of a series of network half-waves (D, E), the half-waves (D) of a first polarity at the beginning of the period (T) and the half-waves (E) of a second polarity at the end of the period (T) are arranged consecutively in the same number depending on the power.

4. The method according to claim 3, characterized characterized in that the polarities of the Half-waves (D, E) cyclically after each period (T) it will be exchanged. 5. The method according to claim 1 or claim 3, because characterized by that a first heating element with the first and a second Heating element with the second polarity of half-waves (A, B, C) or (D, E) is applied. 6. The method according to claim 1 or claim 3, characterized in that a first heating element with the first period (T ₁ ) and a second heating element with the second period (T ₂ ) is applied cyclically. 7. The method according to claim 1 or claim 3, because characterized by that Power control process in one Temperature control is integrated. 8. The method according to claim 1 or claim 3, because characterized in that as Warming device a heat treatment device for scalp hair is provided.