DE4327073C1 - Chopper circuit for DC-isolated transmission of bipolar measurement currents - Google Patents

Abstract

A chopper circuit for DC-isolated transmission of bipolar measurement currents has a 2-way push-pull transformer (4), a chopper circuit (3) on the input side, a control circuit (6) for synchronously driving the transistors (T1 to T4) of the chopper circuit (3) and a 2-way synchronous rectifier circuit (5) on the output side. The chopper circuit (3) consists of two semiconductor switching arrangements (15, 16) which in each case have two bipolar pnp or npn transistors whose emitter-collector paths are connected in parallel with each other. <IMAGE>

Description

The invention relates to a chopper circuit for galvanically isolated Transmission of bipolar measuring currents.

In measurement technology it was previously common to use chopper circuits bipolar transistors unipolar currents with a transmission range of e.g. B. 0 to 20 mA to transmit. Such circuits were not in the Able to transmit negative currents of the same order of magnitude. Of the The reason for this was the fact that the two in the entrance side switching transistors used for the push-pull company of the same type - i.e. B. pnp transistors - were and thus were operated inversely with negative input currents, so that the Current amplification for error-free transmission of the negative on gangsstrom became too small.  

A chopper circuit with a push-pull transformer, with semiconductors circuits which allow current to flow in both directions and which are each connected in series with a transformer winding, with one Control circuit for synchronous control of the switching transistors and with an output-side two-way synchronous rectifier circuit is off U.S. Patent No. 3,517,300. The semiconductor circuits exist in the This chopper circuit consists of two anti-parallel npn transistors ren, so that the problems mentioned above can occur.

From DE 34 07 324 A1 it is basically known to sign correct transmission of bipolar measuring currents to chopper circuits use. More information on the structure of the semiconductor switch in the The chopper circuit cannot be found in the document.

The invention has for its object to start a chopper circuit give, with the help of bipolar currents preferably in the range of -50 up to +50 mA can be transferred with high accuracy.

This object is achieved by the features specified in claim 1 solves. The core of this solution lies in the structure of the input term chopper circuit, each consisting of two semiconductor switching arrangement there is. The latter are in series with the first or two th winding between the center tap of the specified push-pull tragers and an input pole switched. Each of the two  Semiconductor switching arrangements consists of two with their emitter collector gate path parallel to each other, bipolar transistors of the pnp or npn type. Due to the specified parallel connection bipolar Transistors of different types and the synchronous control of the Transistors in a parallel circuit share the current to be transmitted between the transistors so that the one operated in the forward direction Transistor because of the higher current gain the largest part of the leads to transmitted current. The other transistor of each current parallel connection is in inverse operation and only wears un essential to the main flow. With reverse polarity of the on the current is reversed, the in Forward operated transistor of the other type, the reverse polarity operated transistor of the other type is then in inverse operation. That is electricity flow in both directions and thus the galvanically isolated transmission bipolar currents possible.

Claims 2, 3 and 5 relate to advantageous developments of the Chopper circuit in connection with the control of the used Transistors. Through the integration of the jewei specified in claim 2 current control winding for the two transistors of each semiconductor switch Arrangement is caused that the control current only through the two behind interconnected base-collector paths of the two transistors can flow. This leads to the controlled pn junctions of the NPN and PNP transistors of a semiconductor switching arrangement simultaneously direct or block since they are connected in series and therefore both Transistors of the respective semiconductor switching arrangement depending on the polarity of the control current are low or high impedance. This is the beginning called transfer characteristic of the chopper circuit in control technically guaranteed.

In this context, the measure specified in claim 5 serve men in connection with the simple circuitry in accordance with Claim 4, a clean electrical isolation in the transmission bi to achieve polar currents also in the area of the control of the transistors  and to avoid asymmetries in the transmission characteristics.

Because of the doping in the transistor in this type of Control first the pn junction between base and collector conducts, - as specified in claim 2 - the transistors in verse driven. This is only guaranteed if the voltage drop between the collector and emitter of the individual transistors remains low. The voltage drop between the collector and The emitter of each transistor is therefore not allowed to have a value of approx. 40 mV exceed. This presupposes that the chopper according to the invention Circuit is sufficiently terminated on the output side (An Proverb 6). This is ge by a so-called sum point amplifier ensures that is located at the output of the chopper circuit (An Proverb 7). The entire circuit is therefore current controlled.

Further features, details and advantages of the invention are according to following description can be seen in which an embodiment for a chopper circuit according to the invention with reference to the accompanying drawing is explained in more detail.

The drawing shows a circuit diagram of a chopper according to the invention Circuit for the galvanically isolated transmission of bipolar measuring currents.

The chopper circuit shown in the circuit diagram is used for the galvanically isolated transmission of bipolar measuring currents with a transmission range from -20 to +20 mA. The measuring current to be transmitted is fed into the circuit via the two poles 1 , 2 of the input. The circuit itself has various main groups, namely an input-side chopping circuit 3 , a 2-way push-pull transformer 4 , a 2-way synchro rectifier circuit 5 , a control circuit 6 and an output circuit 7 with the two output-side connection poles 8 , 9 .

The two poles 1 , 2 on the input side are connected to one another via a capacitor C1. One connection pole 1 leads to the center connection 10 between the two primary-side windings 11 , 12 of the push-pull transformer 4 . Its other two connections 13 , 14 are connected to the chopper circuit 3 .

The latter consists of two semiconductor switching arrangements 15 and 16 which are connected on the one hand to the connections 13 and 14 and on the other hand to the two terminal pole 2 of the input of the chopper circuit. Both semiconductor switching arrangements 15 and 16 each consist of a pnp transistor T2 or T4 and an npn transistor T1 or T3. The emitters of the transistors T1, T2 and T3, T4 are each connected to the connections 13 and 14 of the two windings 11 and 12 of the push-pull transformer 4 . Your collectors are each connected to the connection terminal 2 . The emitter-collector paths of the transistors T1, T2 and T3, T4 of the respective semiconductor switching arrangement 15 and 16 are connected in parallel.

To control the transistors T1, T2, T3, T4 by means of the control circuit 6 , a control transformer 17 is provided which has two windings 18 , 19 on the input side and two windings 20 , 21 and a feed winding 22 on the output side, electrically isolated therefrom. The latter is used to feed a rectangular control signal with a frequency of approximately 100 kHz to 1 MHz, which is generated by a conventional oscillator 23 . The winding connections 24 , 25 of the winding 18 are connected to the bases of the transistors T3 and T4, respectively. The winding connections 26 , 27 of the winding 19 are connected to the bases of the transistors T2 and T1, respectively.

On the secondary side, the push-pull transformer 4 has two windings 28 , 29 with a center connection 30 and two connections 31 , 32 . The Mittenan circuit 30 is connected to a terminal 8 of the output.

The synchronous rectifier circuit 5 is constructed identically to the chopper circuit 3 and has on the one hand an npn transistor T5 and a pnp transistor T6, the emitters of which are connected to the terminal 31 of the winding 28 and the emitter-collector paths of which are connected in parallel.

Furthermore, the synchronous rectifier circuit 5 has an npn transistor T7 and a pnp transistor T8, the emitters of which are connected to the terminal 32 of the winding 29 and the emitter-collector path is connected in parallel. All collectors of transistors T5, T6, T7 and T8 are connected to a common output line 33 .

To control the transistors T5, T6, T7, T8, the two winding connections 34 , 35 of the winding 20 are connected to the bases of the pnp transistor T8 and the npn transistor T7. In the same way, the two winding connections 36 , 37 of the winding 21 are connected to the base of the npn transistor T6 and the pnp transistor T5.

A capacitor C2 is connected between the output line 33 and the terminal 8 of the output.

The output circuit 7 has a sum point amplifier OV1, whose sen non-inverting input is connected to the connection pole 8 of the output. The output line 33 of the synchronous rectifier circuit 5 is connected to its inverting input. The output of the sum point amplifier OV1 forms the second connection pin 9 from the output of the chopper circuit according to the invention. The output of the sum point amplifier is still coupled back to the inverting input.

The mode of operation of the chopper circuit shown in the circuit diagram is briefly explained below:

• - Transfer of positive polarity current:
  When the transistors T1 and T2 belonging together in pairs are turned on, the pnp transistor T2 is operated in the forward direction and the npn transistor T1 is operated inversely. The pn junctions in these transistors conduct at the same time, since they are connected in series via the winding 19 of the control transformer 17 . The pnp transistor T2 operated in the forward direction transmits the largest proportion of the current to be transmitted due to the higher current amplification. The npn transistor T1 is in inverse operation and contributes only insignificantly to the main current flow. As indicated by points on the winding connections 24 , 26 , 34 , 36 , the two pnp transistors T2 and T4 or the two npn transistors T1 and T3 are each driven in phase opposition, so that when the transistors T1 and T2 are turned on block the other two transistors T3 and T4.
  In push-pull, the npn transistor T3 and the pnp transistor T4 are turned on and the other two transistors T1, T2 are blocked. In this case, there is a current flow from the connection pole 1 via the winding 12 through the two transistors T3, T4 to the connection pole 2 . The main current flow is conducted in an analogous manner through the pnp transistor T4, whereas the inversely operated npn transistor T3 only makes a minor contribution to the current flow.
  Because of the above control, the direct current at the input is "chopped" and transmitted via the push-pull transformer 4 to the 3-way synchronous rectifier circuit 5 , which is controlled and operates in an analog manner. As a result, a current is transmitted to the output in an electrically isolated manner, the size and polarity of which correspond to the output current.
• - Transmission of negative polarity current:
  When the transistors T1, T2 are turned on, the npn transistor T1 is operated in the forward direction and the pnp transistor T2 is operated inversely. This in turn means that the main current flow is conducted through the npn transistor T1, whereas the pnp transistor T2 only makes a minor contribution to the current flow. The two transistors T3, T4 block. When the two transistors T3, T4 are turned on, the main current flows in an analog manner via the npn transistor T3, which is operated in the forward direction. As was by the mutual control of the transistors T1, T2 and T3, T4, the input current of negative polarity "chopped", freely transmitted via the push-pull transformer 4 , rectified by the synchronous rectifier circuit 5 and output via the low-impedance output circuit 7 .

In both cases, the transistors T5 to T8 are synchronous rectifier circuit so controlled that the main current flow on the on on the output and output side, transistors always different Chen type contribute. This causes asymmetries in the transmission scheme characteristics avoided.

Claims (7)

1. Chopper circuit for the galvanically isolated transmission of bipolar measuring currents with

• - A 2-way push-pull transformer ( 4 ) with two windings ( 11 , 12 , 28 , 29 ) on the primary and secondary side, with a first connection pole ( 1 ) of the input of the chopper circuit on the input-side center connection ( 10 ) of the push-pull transformer ( 4 ) is connected,
• - An input-side chopper circuit ( 3 ), consisting of two semiconductor switching arrangements ( 15 , 16 ), each in series with the first or second winding ( 11 , 12 ) between this first and second winding ( 11 , 12 ) and second input-side circuit terminal ( 2 ) of the chopper circuit are connected, each of the two semiconductor switching arrangements ( 15 , 16 ) consisting of two bipolar transistors (T1 or T2; T3) connected in parallel with one another with their emitter-collector path or T4) of the pnp or npn type,
• - A control circuit ( 6 ) for synchronous control of the transistors (T1, T2 or T3, T4) of a parallel circuit and
• - An output-side 2-way synchronous rectifier circuit ( 5 ).

2. Chopper circuit according to claim 1, wherein the control of the transistors (T1 to T8) takes place by means of a control transformer ( 17 ), which is fed by an oscillator ( 23 ) fed infeed winding ( 22 ) and in each case one control winding ( 18 , 19 ) for each semiconductor switching arrangement ( 15 , 16 ), which control windings ( 18 , 19 ) each in series between the base-collector paths of the two parallel-connected transistors (T1, T2 or T3, T4) of each of the two semiconductor switching arrangements ( 15 or 16 ) are switched. 3. Chopper circuit according to claim 2, wherein the transistors (T1, T3 or T2, T4) of the same type in the two semiconductor switching arrangements ( 15 , 16 ) are driven in phase opposition. 4. Chopper circuit according to one of claims 1 to 3, wherein the from the 2-way synchronous rectifier circuit ( 5 ) is constructed identically to a chopper circuit ( 3 ) on the output side. 5. Chopper circuit according to claim 4, wherein for controlling the synchro rectifier circuit ( 5 ) corresponding control windings ( 20 , 21 ) on the control transformer ( 17 ) are provided, the gene from the Steuerwicklun ( 18 , 19 ) for the input-side semiconductor switching arrangements ( 15 , 16 ) are isolated and which control the transistors (T5, T6, T7, T8) of the synchronous rectifier circuit ( 5 ) such that transistors of different types contribute to the main current flow on the input and output sides. 6. Chopper circuit according to one of claims 1 to 5, wherein the output side synchronous rectifier circuit ( 5 ) is terminated with low resistance. 7. chopper circuit according to claim 6, wherein the synchronous rectifier circuit ( 5 ) by a sum point amplifier (OV1) is completed.