DE19948313A1 - Electric heating and method for regulating an electric heating - Google Patents

Abstract

An electric heating installation (1) has at least two electric heating resistances (2) whose heating power can be cascaded by a control device (3). The control device has a controller (4) corresponding to the number of heating resistances which are each assigned to one heating resistance. The control device supplies each controller separately with a clocked pulse-shaped current. The controllers are controlled with a pulse-controlled modulation of the control device. The current pulses to the respective controller are displaced towards each other in time. The current pulses at the respective controller overlap each other in displaced time fashion. The heating resistances are PTC elements.

Description

The invention is based on an electric heater and a Process for regulating an electric heater according to the genus independent claims.

Heaters for motor vehicles with heat sources from one Power semiconductors generated heat are used from the state known in the art. So in WO 99/07185 an electrical Heating for a motor vehicle described in which the heat source heat generated by power semiconductors is used. This emitted heat is used directly for heating. The Power semiconductors are regulated via control circuits in order to To be able to continuously adjust the heating output. Providing the heat Power semiconductors are either connected in parallel or several Current branches, each with two connected in series and in High power loss operation operated power semiconductors in parallel switched. The regulation of the heating power is based on this Technology simply possible by using a power semiconductor jointly specifiable setpoint and by means of Power semiconductors derived actual values in the output power are individually adjustable. For this individual regulation a complex control circuit required.  

Also known from the prior art as the heaters design multi-stage systems with several heating resistors. The individual heating levels are spatially in a flat structure separate strips, each corresponding to a heating resistor, arranged. The heating output is controlled by switching on or switching off the individual stages. Each one Stage switched by a switching means. The regulation of such In this case, the heating system is made by combining the stages and theirs On / off states. By switching the discrete heating levels the heating does not heat evenly over the entire surface. The too warming air that flows through the heating elements knows no homogeneous Temperature profile. Is the air flowing through after the Flow through the heating elements is not sufficiently mixed or individual heating levels the air channels for heating individual Assigned vehicle areas, it can result in one Motor vehicle heated an area of the passenger compartment, but another with cold air is supplied.

The electric heater according to the invention with the characteristic Features of the independent claim have the advantage over the that mixing the air with only partial activity of individuals Heating levels can be omitted. This reduces the effort, for example mechanical components for thorough mixing reduced. Furthermore, by the heater according to the invention a uniform use of all Guaranteed heating levels, and so wear on all existing Heating levels and thus distributed to all heating resistors.

By the measures listed in the subclaims advantageous developments and improvements in the independent Claim specified electrical heating possible.

It is particularly advantageous that a simple, conventionally available Control procedures for how pulse width control is used.  

The inventive method for controlling an electrical heater allows the target temperature of the cell to be heated, for example one Passenger compartment of a motor vehicle to regulate in a simple manner. With Pulse width control is a simple, continuous control possible from an actual temperature to a target temperature. The Pulse width control is made possible by setting the respective Duration of the current pulses and the chronological sequence of the current pulses flexible control of the heater according to the invention.

An embodiment of the invention is shown in the drawings and explained in more detail in the following description. It shows:

Fig. 1 schematically shows the construction according to the invention a heater,

Fig. 2 is a pulse width control with low heating power and

Fig. 3 shows a pulse width control with high heating power.

In Fig. 1, an electric heater 1 is shown schematically. A control device 3 contains controllers. The controllers 4 are each connected to a heating resistor 2 . The levels are designated with the Roman numerals I, II, III and IV. The output of the electrical heating resistors 2 is open to the heated cell 5 . The electrical contacts of the control device 3 are not shown any further, nor are the air guide channels through the heating resistors 2 .

FIG. 2 shows how the heating resistors 2 can be operated with quasi-continuous power by means of a pulse width control of the control device 3 . The frequency of the pulse width control is to be selected such that a quasi-steady state is achieved for the heating of the heating resistors 2 , and on the other hand the load on the generator, particularly in a motor vehicle, does not reach any noticeable fluctuations. A fluctuation in the vehicle electrical system below the 40 Hz that can be resolved by the human eye would be noticeable, for example, in the lighting of the vehicle. With a switching frequency of approximately 100 Hz, the fluctuation in the voltage of the vehicle electrical system can no longer be resolved and is therefore no longer recognizable to humans. In order to heat the heating resistors 2 evenly, the individual stages I, II, III, IV are switched on sequentially. In order to keep the fluctuations in the vehicle electrical system low, the switching frequency of 100 Hz is divided down into the number of stages. In the example of FIG. 2 and the four heating resistors 2 , the individual stages are clocked at 25 Hz each. This is sufficient to bring the heating resistors into a quasi-stationary thermal state, which allows an optimal efficiency. Depending on the control power, the duty cycle for each individual heating resistor can take place within the time interval until the next stage switches on.

In Fig. 3 it is shown that the duty cycle of the stages can also extend beyond the switch-on point of the following stages. In any case, the individual heating resistor of the stage is switched off before the time of the new switching sequence of this stage, except at maximum power. So-called PTC (positive temperature coefficient) elements, as are known for example from EP 0 895 440 A2, are preferably used as heating elements. PTC heating elements, for example thermistors, are used in the prior art like heaters. These components have the advantage that they are self-regulating with the temperature and cannot be overheated. It is precisely this positive behavior with circuits with abnormally high currents that makes them popular in compact heaters. The use of PTC elements is particularly advantageous for the electrical heating according to the invention. The elements achieve a quasi-steady state due to the clocked control. Overshoot of the control due to steep pulse edges are suppressed in the PTC element. This means that there are no high demands on the design of the electronic control.

According to the method according to the invention, a Temperature difference between the target temperature and the actual temperature determined. This temperature difference represents the controlled variable for the Pulse width control. If the difference is large, a high heating cable  required to achieve the compensation quickly. The pulse width control regulates current pulses with large at the respective heating resistors Pulse duration. The current pulses of the individual heating resistors overlap temporally, so that an integral large heating line results.

It is also conceivable to use a control system in which the Heating resistors in the case of maximum heating output with a continuous one Electricity can be operated and only when the heating cable is reduced The current is clocked.

Claims (6)

1. Electric heater ( 1 ) with at least two electric heating resistors ( 2 ), the heating power of which can be cascaded by a control device ( 3 ), characterized in that the control device ( 3 ) has a controller ( 4 ) corresponding to the number of heating resistors ( 2 ) Each of which is assigned to a heating resistor ( 2 ), the control device ( 3 ) separately supplying each controller ( 4 ) with a pulsed, pulsed current. 2. Electric heater according to claim 1, characterized in that the controller ( 4 ) with a pulse width control of the control device ( 3 ) are controlled. 3. Electric heater according to claim 1 or 2, characterized in that the current pulses to the respective controller ( 4 ) are shifted in time against each other. 4. Electric heater according to claim 3, characterized in that the current pulses on the respective controller ( 4 ) overlap in time shift. 5. Electric heater according to claim 1, characterized in that the Heating resistors are PTC elements. 6. Method for controlling an electric heater consisting of at least two heating resistors ( 2 ) and a control unit ( 3 ),

• a target temperature in the cell to be heated is compared with an actual temperature,
• - The control circuit outputs pulsed time-delayed currents to the regulators of the heating resistors, and
• - The duration of the pulses is set depending on the difference in temperatures.