DE2028455C - Starting device for a single-phase asynchronous motor - Google Patents

Description

which the control electrode of the semiconductor valve is connected, the transistor at least in Zero crossing is in the locked state.

With this arrangement, the capacitor is not only fed via the control path of the controlled rectifier, but also discharged via an additional discharge circle. This discharge circuit ensures that after each charge the voltage across the capacitor drops relatively quickly, so that only then an ignition takes place in the next zero passage if the charging voltage is sufficient On the other hand, the charging voltage was only slightly higher than the ignition voltage of the Lag Semiconductor valve, finds neither in the following nor in one of the next zero crossings Ignition instead. At the zero crossing, the transistor blocks, i.e. interrupts the charging circuit, and the full customer generator voltage can act on the control electrode. Since the ignition of the controlled Rectifier takes place approximately in the zero crossing, contains the voltage flowing in the starting winding circuit little harmonics. This prevents interferences in the network and in radio reception.

In the case of a starting device in which the capacitor is charged via a half-wave rectifier and has such a large discharge time constant that or during the start-up process is also at the second subsequent zero passage a voltage sufficient to ignite the semiconductor valve has, it is advantageous if the transistor also during that half-cycle in which the capacitor is not charging, is locked. The main discharge of the capacitor takes place here immediately after charging. If the ignition voltage of the! do not sign the semiconductor valve, so i «· they, apart from the slight losses over the control path of the valve, aurh still received in the next zero ditch, because during this time the discharge current is made circular ineffective.

In a preferred embodiment, it is ensured that the base-emitter path of the transistor is bridged by a diode polarized against its forward direction and via a series resistor is due to the decreasing AC voltage. It is thus achieved in a simple manner that the transistor nu 'goes into the conductive state in every second half-wave. It stays short at one point in time before a zero crossing up to a point in time shortly after the next zero crossing in the blocked state. Every time the capacitor is charged by the maximum amplitude of the decreasing voltage has been, a brief discharge takes place, which is the control voltage at the end of the start-up period for the semiconductor valve certainly brings it below the ignition value.

In another embodiment, it is ensured that the emitter of the transistor with the one pole of the semiconductor valve and the base via a series resistor and a diode with the other Pole of the fall leak valve is connected, this diode in the forward direction of the base-emitter path is polarized. With this circuit, the transistor remains in the blocking state as long as the semiconductor valve is open is ignited immediately in the zero crossing. But if the capacitor voltage is no longer to the If ignition in the zero crossing is sufficient, the transistor is switched to the conductive state. So is Any possibility of ignition for the semiconductor valve is prevented, even if the decreasing voltage S should reach a value that exceeds the ignition value.

The decreasing alternating voltage is preferably applied to a fixed resistor and a voltage divider having a PTC resistor is tapped. Increased with this voltage divider

xo is the resistance value of the PTC resistor as a result Warming over time, so that the length of the start-up process can be determined in this way. A series resistor is particularly advantageous between the semiconductor valve and the starting winding and, if necessary, a starting capacitor connected, and the voltage divider bridges the semiconductor valve and the series resistor. Since the semiconductor valve substantially during the entire period is ignited and the W ^ first value of the starting

ao winding current flowing through the series resistor small is compared to the resistance value of the voltage divider, there is approximately one at the voltage divider constant voltage, which is divided in the desired way with the help of the PTC resistor.

As the invention is hereinafter referred to as a child In the drawing illustrated embodiment explained in more detail. It shows ».

Fig. 1 is a circuit diagram of the starting device according to the invention,

F i g. 2 shows some voltages occurring in the circuit and in a time diagram

F i g. 3 is a circuit diagram of another embodiment of the invention.
A running winding 3 and a starting winding 4 of a single-phase asynchronous motor are connected to the mains terminals 1 and 2 of a single-phase alternating current network. A starting capacitor 5, a series resistor 6 and a semiconductor valve 7 which is permeable in both current directions and which has a control electrode 8 are connected in series with the starting winding 4. A voltage divider, consisting of an ohmic resistor 9 and a PTC resistor 10, bridges the series resistor 6 and the semiconductor valve 7. At the tap 11 of the voltage divider

an alternating voltage is tapped which, with the interposition of a control circuit 12, forms the control electrode 8 of the semiconductor valve 7 influenced

In the control circuit 12 there is a capacitor 13, which is e ^; NEN half-wave rectifier 14 from the voltage

voltage drop across resistor 9 is charged. The capacitor 13 is assigned a discharge circuit, the consists of a resistor 15 and the coil-emitter path of a transistor 16. At one point 17, the control electrode 8 is connected between these two elements. The base of the transistor

16 is connected to tap 11 via a series resistor 18. The base-emitter path 16 is through an oppositely connected diode 19 bridged.

Switching on takes place with the aid of a switch 20.

The mode of operation is as follows: When the switch 20 is inserted, a current flows through the main winding 3 and via the series connection of the elements 9, 10, 5, 4. As a result, an alternating voltage U ₁₁ results at the resistor 9, which, since the PTC

Resistor 18 gradually warms up, decreasing during the start-up process. Because of the half-wave rectifier 14, the capacitor 13 is only influenced by every second half-wave U _{0 of} the voltage U ₁₁ .

5 6

The voltage U _u is also at the base-emitter-emitter of the transistor 16 connected pole opposite-

Path of the transistor 16. But because this is overlaid by the.

Diode 19 in which one half-wave is short-circuited, the transistor is located in this circuit

this base-emitter path from the span is also in the blocking state, as long as the semiconductor element! 7th

voltage U _G controlled. If the voltage U _{BE is} that 5 from the voltage of the capacitor 13 in each case

Is the voltage at which the transistor is ignited in the conductive zero crossing. Is the capacitor

State passes, the transistor is during the voltage 13 but dropped to a value that

Periods ζ blocked. is no longer sufficient to ignite, the valve remains

The voltage U _c on the capacitor has the following til 7 following the zero crossing, curve: The capacitor is charged up to the maximum 10 and the transistor 16 is charged to the conductive state of the voltage U _0. Then he is steered over. Then it is ensured that no ignition discharge circuit with the resistor 15 and the manure of the valve 7 can take place, even if the transistor 16 is discharging, until shortly before the first the voltage drop across the resistor 9 a maximum zero crossing I ₁ the transistor in the blocking state malwert should reach, which passes over the ignition chip and then a discharge of the condensation U _{1 of} the valve 7 is located. The blocking of the half gate 13 is only possible to the extent of the leakage currents head valve therefore takes place momentarily. This Wirist. Shortly after the second zero crossing I ₁ , this corresponds to that of an on-off switch, transistor 16 becomes conductive again, and the condenser switch.

Sator is further discharged until the voltage U ₀ as- According to an embodiment for the F i g. 3

who takes over the charge. This game again - 20 the following values were provided:

catches up in every second half-wave. Resistance 9 330 ohms

As soon as the transistor 16 blocks, the full PTC resistance is 10 ... 1000 ohms

Capacitor voltage U _c at the control electrode 8. in the cold state

It can be seen from FIG. 2 that in each zero-cross series resistor 6 25 ohms

output I ₁ , I ₂ , 1 ₃ etc. at the control electrode 8 one of the> ₅ series resistor 21 47 kiloohms

Capacitor supplied control voltage U _Sl or discharge resistance 15 .. 220 Ohm

U _Si cherishes, although this capacitor is only in each capacitor 13 100 ,, F

second half-wave is charged The semiconductor starting capacitor 5 .. 120 ,, F

valve 7 ofTnet therefore at the beginning of each half-wave, see above

that the starting winding 4 with the full alternating 30 The circuit has the further advantage that one

electricity is supplied. This game continues until a very cheap starting capacitor 5 is used.

the control voltage U _Si or U _Si the ignition voltage, which at a mains voltage of 200 volts only

voltage falls below U ₁ , which must be at least loadable at the control unit with 150VoIt. while dci

electrode 8 must be. so that the valve 7 ignites. same starting capacitor when connected

In the embodiment according to FIG. 3 are used with a normal starting relay for 35, one

the same components must be able to withstand voltages of over 300 volts with the same reference symbols

used. The difference to the F i g. 1 consists in, If the rotor is blocked, dci will heat up

that the base of the transistor 16 via a pre-PTC resistor 10, so that after the predetermined

resistor 21 and a diode 22. which blocks valve 7 in the direction of the start-up period. The Startwick

the base-emitter-path is poH, with a 40 lung 4 can therefore not be overloaded.

Point 23 is connected; This point is due to the voltage divider 9, 10 can also be immediate

that pole of the semiconductor valve 7 that is connected to the between the two power connections.

1 sheet of drawings

Claims (6)

depending on an alternating voltage which decreases during the start-up phase, with decreasing voltage between the points 1. Starting device for a single phase and the control electrode of the semiconductor valve asynchronous motor with a start winding and with 5 a control circuit is connected, which stores the voltage with a capacitor that is permeable for both directions of current, so that it saves the minimum controlled semiconductor valve that is connected to the start steos lies in the next following phase transition for winding in series and is available depending on the control of the semiconductor valve
a decrease during the start-up process- From Fig. 3 of the USA.-Patent 3421064 the AC voltage is controlled, whereby an outlet device of this type is known, in which see the point of decreasing voltage and in the starting winding branch one for both current direction control electrodes Semiconductor valve a control permeable, controlled semiconductor valve is connected upstream, which the voltage can be seen by means of whose control electrode stores the voltage of a capacitor in such a way that it is fed to at least one capacitor. The condensate in the next phase zero crossing 15 sator is available via a one-way rectifier from a voltage that decreases during start-up for the control of the semiconductor valve, characterized in that the feeds between a free end of the main condenser (13) a Discharge circuit has, which consists of winding and the free end of an additional, a resistor (15) and the collector-emitter at a tap of the main winding Anschlov path of a transistor (16), is tapped between ao sen winding. The capacitor to which the control electrode (8) of the semiconductor vein is connected to the peak value tils (7) in every second half-cycle, the transistor being charged with the voltage. He can only get through at least the zero crossing in the locked state. Discharge the control path of the semiconductor valve. Since the 2. Starting device according to claim 1, in which this flow len currents are very low, remains the capacitor via a half-wave rectifier 35, the voltage across the capacitor is largely constant, is charged and such a large discharge time- As a result, the capacitor only needs in each constant has that it will be charged during the start-up pre- second half-wave; despite this even with the second following zero there is a sufficient control voltage in two passages one for the one of the semiconductor successive zero crossings available, valve has sufficient voltage, thus 30 With this circuit, the control voltage is sufficient characterized in that the T.ansistor (16) can also be used to ignite for a long time during the half-cycle in which the condenser is off, if no recharging of the condenser at all is not charging, is in the locked state. more is done because the charging voltage in their 3. Starting device according to claim 1 or 2, maximum value smaller than the capacitor voltage characterized in that the base-emitter is 35. This is not the end of the start-up process Route of the transistor (16) by a counter more precisely definable. This is especially true for the its forward direction polarized diode (19) over- Normalfail that the amplitude of the capacitor is bridged and via a series resistor (18) to charging alternating voltage towards the end of the other decreasing AC voltage. running process decreases relatively quickly. 4. Starting device according to claim 1 or 2, 40 from Swiss patent specification 472 806 is characterized in that the emitter of a starting circuit with one in both Stromrich transistor (16) with one pole of the halved-permeable, controlled semiconductor valve ladder valve (7) and the base via a pre-known whose control electrode with the help of a resistor (21) and a diode (22) with the PTC resistor directly to a point of the other pole of the semiconductor valve is connected, 45 starting winding branch is laid. This diode in the forward direction of Aus der US Pat. No. 3,307,093 is an an-base-emitter path is polarized. known circuit, in which with the help of an additional 5. Device according to one of claims 1 winding and via an amplifier transistor one to 4, characterized in that the decreasing pulse generator is controlled, in which a capacitor mende alternating voltage is charged to a fixed 50 and when a threshold value span resistance is reached ( 9) and a PTC resistor (10) voltage via a unijunction transistor having discharged voltage divider is tapped. _w i _r d. One of these impulses is controlled 6. Apparatus according to claim 5, characterized in that the rectifier is controlled in the starting winding branch. The characterized that between the semiconductor circuit is intended to change the ignition timing of the valve (7) and the start winding (4) a series resistor 55 controlled rectifier is connected to the voltage level (6) and the voltage divider voltage curve at the start winding to influence. (9,10) the semiconductor valve and the Vorwider- This, however, is bridged with strong harmonic waves. Voltage curves. The invention is based on the object of a 60 starting device of the type described above indicate, in which the advantages associated with a storage capacitor are used, anyway but a defined termination of the start-up The invention relates to a starting process is ensured. direction for a single-phase asynchronous motor with 65 This object is thereby geeincr according to the invention Starting winding and with a current for both triggers that the capacitor has a discharge circuit, permeable, controlled semiconductors consisting of a resistor and the collector valve, which is in series with the start winding and the emitter path of a transistor, between