DE3302609A1 - Circuit arrangement for power supply - Google Patents

Abstract

A hairdryer is equipped with two parallel-connected heating resistors (20, 24) and can be connected via three switches (26, 28, 30) to a voltage source (10, 40). Connected between the heating resistors (20, 24) is a fan motor (42) which is connected on its one side to a cathode connecting line (46) of two diodes (48, 50) and on its other side to the first heating resistor (20). Connected in parallel with the first diode (48) is a third diode (56) which is connected at one end to the output (31) of the first heating resistor (20) and at the other end to the output of the fan motor (42). The two diodes (48, 50) are connected asymmetrically to the two heating resistors (20, 24) in such a manner that the half cycles flowing via the first and second diodes (48, 50) are of different magnitude. In consequence, the speeds for the fan motor can be adjusted in fine steps. <IMAGE>

Description

Circuit arrangement for power supply

04869 The invention relates to a circuit arrangement to power two between the poles of an AC voltage source in parallel arranged, each switchable via a switch heating resistors and one between the heating resistors switched fan motor, with at least one side of the fan motor to a line connecting the cathode sides of two diodes connected.

A circuit arrangement is already known (DE-A1 31 33 325.7), the power supply for two in parallel between the poles of an AC voltage source arranged heating resistors is used, which is operated alternately via three switching contacts can be in this way different heating outputs at different Set speeds. For this purpose, there is a fan motor between the heating resistors switched with its input side and its output side to the connecting lines two interconnected diodes is connected, one diode over their cathode side to the Mlttelabgriff of one heating resistor and the other The diode with its anode cable is connected to the middle tap of the other heating resistor is. The two other diodes are connected to the power supply line via a connection line connected. So that the heating resistors also over, for example, only one half-wave can be operated, a diode in the power supply line is parallel arranged to a switch.

In contrast, the invention is based on the object of the circuit arrangement to train in such a way that a finer gradation for the engine speed is achieved. This object has been achieved in that the first diode is connected to the first heating resistor and the second diode on the second heating resistor in such a way asymmetrical to the first Diode is connected that the half-waves running through the first and second diode are of different sizes, with at least a third diode in parallel with the fan motor is switched. Due to the asymmetrical tapping of the diodes on the two heating resistors you get half-waves of different sizes and thus a better gradation of the individual speeds for the fan motor. For this purpose it is advantageous that the fan motor with its one connection to the cathode sides the first and second Diode and with its other connection directly to a voltage tap of the first Heating resistor is connected, the first diode in parallel with the fan motor is switched.

It is also advantageous that in addition to the two diodes, the third a diode connected in parallel to the first diode and to the fan motor is provided, with their anode side to the output of the first heating resistor and with their Cathode side is connected to the connection of the fan motor with the cathode sides the first and second diode is connected. Due to the asymmetrical connection of the Diodes on the heating resistors result in three different amplitudes and thus different speeds for the engine.

By adding the third diode, a third half-wave is created a third correspondingly larger or smaller amplitude created, which, depending on the position of the three switches for operating the heating resistors, the corresponding engine speed for the fan motor generated.

In a further embodiment of the invention, it is advantageous that on the output side of the second heating resistor is the cathode side of a fourth diode is connected, the anode side of which is connected to the two outputs of the heating resistors connecting line is connected, which is connected to the voltage source, wherein between the output side of the second heating resistor and the cathode side the fourth diode has a line connected to the anode side of the second Diode is connected with your cathode side to the cathode side of the first Diode is connected. It is also advantageous that the two are connected to the inputs of the heating resistor connected lines each have a switch and with are connected to a line connected to the voltage source, in which one Diode is provided with a switch arranged in parallel therewith.

By adding a fourth diode connected to the output of one Heating resistor is connected, runs, for example, in half-wave operation entire current through the one heating resistor and thus to the motor, so that this with low heating output also one very low speed for the Fan motor can be adjusted. The large speed graduation for the fan motor can be achieved with just three switches that can be operated alternatively will.

In the drawing there are two exemplary elements of a circuit arrangement shown schematically according to the invention. It shows: FIG. 1 a circuit diagram two connected in parallel, arranged between the poles of an AC voltage source Heating resistors with a rectifier circuit; Figure 2 shows another embodiment similar to FIG. 1, but with an additional diode.

In the drawing, 10 is connected to an AC voltage source Pole denotes that via an input line 12 with the anode side of a diode 14 is connected. The cathode side of the diode 14 is connected to a connecting line 16 connected to an input 18 of a first heating resistor 20 and to an input 22 of a second heating resistor 24 is connected. The first Heating resistor 20 is via a switch provided in connecting line 16 26 and the second heating resistor 24 via one also in the connecting line provided switch 28 can be connected to the AC voltage source 10. The switches 26 and 28 can be designed to be actuatable individually or together. A third switch 30 is connected upstream of the two switches 26 and 28 and in parallel arranged to the diode 14, so that when the switch is open 30 half-wave operation and when switch 30 is closed, full wave operation prevails.

The first heating resistor 20 has an output 31 which has a further connecting line 34 with an output 32 of the second heating resistor 24 is connected. The connecting line 34 is via a neutral conductor 38 with a Pole 40 connected, which is also connected to the AC voltage source.

There is one between the two heating resistors 20 and 24 Rectifier circuit formed from several diodes with a fan motor 42, one side of which is connected to a voltage tap 44 of the first heating resistor 20 and is connected with its other side to a connecting line 46. The connecting line 46 connects the cathode side to a first diode 48 the cathode side of a second diode 50. The anode side of the first diode 48 is connected to the first heating resistor 20 via a second voltage tap 52, while the anode side of the second diode 50 is connected to a first voltage tap 54 of the second heating resistor 24 is connected. The second voltage tap 52 can be designed as a central tap, while the first voltage tap 54 on the second heating resistor 24 with respect to the second heating resistor 24 asymmetrically connected. The series resistor formed from the first heating resistor 20 R 1 for the first diode 48 is slightly larger than the series resistor R 2 from the second heating resistor 24 is formed. That way the amplitude is over the heating resistor 20 runs, smaller than the amplitude across the second heating resistor 24 is running. As can be seen from Figure 1, the first diode 48 is parallel to the fan motor 42 and connected in parallel to a third diode 56. The third diode 56 is with its anode side to the output of the first heating resistor 20 and with its cathode side to the connecting line 46 of the first and second diode 48 and 50 connected.

In the exemplary embodiment according to FIG. 2, in addition to the three diodes 48, 50 and 56 a fourth diode 60 is provided, the cathode side of which is connected to the output 32 of the second heating resistor 24 and with its anode side to the connecting line 34 is connected. Between the output 32 of the second heating resistor 24 and the anode side of the second diode 50 is connected to the cathode side of the diode 60.

In the table, the switch positions of switches 26 = S 1, 28 = S 2 and 30 = S 3, where logical zero switch = open and logical 1 Switch = closed means.

If all three switches 26, 28 and 30 are brought into a closed position, so there is full-wave operation, since the positive half-wave with the amplitude A 1 over the diode 14 and the switch 26 and via the switch 28 and via the associated Heating resistors 20 and 24 runs while the negative half-wave over the switch 30 as well as switches 26 and 28 and the two heating resistors 20 and 24 runs, so that the full heating power of 1000 W is available.

In all cases, the working voltage for the fan motor 42 is dependent on the voltage drop of the respective heating resistors 20 and 24 in operation. The two heating resistors 20 and 24 can therefore also be completely different are designed and the fan motor 42 receives a switched on in each case Heating power freely determinable working current. In the present case, with three closed Switches, a speed for the fan motor 42 results from the voltage drop over which the diode D 2 and D 3 taking into account the series resistor R 2 des Heating resistor 24 and the post-resistor R 3 of the heating resistor 20.

If switches 26 and 30 are closed and switch 28 is open, so the positive and negative half-wave flows through the switches 26 and 30 and the Heating resistor 20, so that a heating power of 600 watts is available at a speed which results from the voltage drop across the diode D 1 and D 3.

If the switch 30 is open and the two switches 26 and 28 are closed, only the positive half-wave flows through the switches 26 and 28 and thus via the heating resistors 20 and 24, so that when both Resistors of 1000 watts only have half the heating power of 500 watts available stands. The speed for the fan motor 42 results from the voltage drop via the diode (D 2) 50 and the motor output at the voltage tap 44.

If the two switches 28 and 30 are closed, full-wave operation prevails, so that the positive and negative half-wave flows through the switch 30, both half-waves are passed through the heating resistor 24 and thus a heating power of 400 watts. The speed at this heating output results from the voltage drop across the diode (D 2) 50 and the voltage tap 44.

Closing the switch 26 results in half-wave operation, since only the positive half-wave through the diode 14 and thus through the switch 26 and over the first heating resistor 20 is conducted and thereby a heating power of 300 Watt is available. The speed at this heating output results from the Voltage drop across diode D 2 and the motor output at voltage tap 44.

By closing the switch 28, half-wave operation prevails again at partial load, since now the half-wave through the diode 14 and the switch 28 and thus runs over the heating resistor 24, so that a heating power of 200 watts for Available. With this heating output, a speed is set that from the voltage drop across the diode (D 2) 50 and the motor output respectively the voltage tap 44 results.

The circuit arrangement in FIG. 2 differs in its mode of operation only slightly different from the circuit arrangement according to FIG. 1. In FIG a diode 60 connected to the output 32 of the heating resistor 24, the diode 50 between the cathode side of the diode 60 and the output 32 of the heating resistor 24 is connected, so that the amplitude that runs across the heating resistor 24, according to Figure 2 is smaller than the amplitude of Figure 1 at the center tap Diode 50. If, for example, only switch 28 is closed, the result is in half-wave operation via the right heating resistor 24 the smallest adjustable Speed, since now the entire current through the heating resistor 24 and only then running to motor 42. The speed for a switch position according to table no. 7 is according to the switching arrangement according to FIG. 2, less than the speed of the switching arrangement according to FIG. 1 with the switch 28 closed.

The heating outputs according to the switching arrangement according to FIG. 2 can be in the same way by closing the individual switches accordingly as with the switching arrangement according to Figure 1 set.

Table switch position Switch (30) (26) (28) 5 1 5 2 5 3 N (Watt) Speed mode n-1 1 0 0 0 0 W Off 2 1 1 1 1000 W n 1/3 full wave operation 3 1 1 0 600 W n 1/2 full wave operation without heating load 400 W 4 0 1 1 500 W n 3 half wave operation over Do 5 1 0 1 400 W n 3 full wave operation without heating load 600 W 6 0 1 0 300 W n 2 half-wave operation without heating load 400 W 7 0 0 1 200 W n 3 half-wave operation without Heating load 600 W O = open 1 = closed List of terms 10 pole 12 Input line 14 diode 16 connection line 18 input 20 1st heating resistor 22 Input 24 2nd heating resistor 26 switch 28 switch 30 switch 31 output 32 output 34 Connection line 38 Neutral conductor 40 Pole 42 Fan motor 44 Voltage tap 46 Connection line 48 1st diode 50 2nd diode 52 2nd voltage tap 54 1st voltage tap 56 3rd diode 60 4th diode

Claims (5)

Circuit arrangement for power supply at least two arranged in parallel between the poles (10, 40) of an alternating voltage source, each via a switch (26, 28) switchable heating resistors (20, 24) and one between the heating resistors (20, 24) switched fan motor (42), at least the one side of the fan motor (42) to one of the cathode sides of two diodes (48, 50) connecting line (46) is connected, characterized in that the first diode (48) to the first heating resistor (20) and the second diode (50) the second heating resistor (24) so connected asymmetrically to the first diode is that the half-waves running across the first and second diodes (48, 50) are different are large, with at least one third diode (56) parallel to the fan motor (42) is switched. 2. Circuit arrangement according to claim 1, characterized in that the fan motor (42) with its one connection to the cathode sides of the first and second diode (48, 50) and with its other connection directly to a voltage tap (44) of the first heating resistor (20) is connected, the first diode (48) is connected in parallel to the fan motor (42). 3. Circuit arrangement according to Claims 1 and 2, characterized in that that in addition to the two diodes (48, 50) the third, parallel to the first diode (48) and to the fan motor (42) connected diode (56) is provided, which with its anode side to the output of the first heating resistor (20) and with its cathode side to the Connection of the fan motor (42) is connected to the cathode sides of the first and second diode (48, 50) is connected. 4. Circuit arrangement according to one or more of the preceding Claims, characterized in that on the output side of the second heating resistor (24) the cathode side of a fourth diode (60) is connected, the anode side of which to the line (34) connecting the two outputs of the heating resistors (20, 24) is connected, which is connected to the voltage source, wherein between the Output side of the second heating resistor (24) and the cathode side of the fourth Diode (60) has a lead connected to the anode side of the second diode (50) is connected with its cathode side to the cathode side of the first Diode (48) is connected. 5. Circuit arrangement according to one or more of the preceding Claims, characterized in that the two are connected to the inputs of the heating resistor (20, 24) connected lines (16) each have a switch (26, 28) and are connected to a line (12) connected to the voltage source (10), In which a diode (14) with a switch (30) arranged in parallel is provided is.