Inductive device

Abstract

 An inductive device such as a transformer has a multi-turn magnetic core (16) disposed about a conductor loop (20). A bridge transformer (Fig. 2) has one turn of the core about one half of the conductor loop and a second turn of the core about the other half of the conductor loop, and an electrical centre tap connection (132) to the loop between the two halves thereof. Embedded diodes (110, 112) connect the ends of the loop to an external circuit.

Description

[0001] This invention relates to an inductive device and more particularly, but not exclusively, to an electrical transformer.

[0002] Customarily, an electrical transformer comprises a magnetic flux path defining core, and input and output windings linking the flux carried by that core, with the input to output transformation (voltage and current) being determined by the turns ratio of the input and output windings. In many cases it is desirable to have an output winding consisting of a single turn for ease of fabrication. An example is seen in high current output transformers where the secondary may be made from thick bar-like conductor material which is impractical to form into multiple turns.

[0003] Moreover, high current output secondary windings in a power transformer may generate significant heat which must be transferred to adjacent structures. For this reason it is desirable to form the secondary winding as a simple, flat structure having an abundant heat transfer surface. This cooling requirement militates against provision of plural turns in such a winding. If traditional single flux turn magnetic structures are used, this single turn secondary winding requirement places design constraints on the primary winding for a given transformation ratio objective.

[0004] There are cases in which it is necessary to provide a centre tap to a transformer winding. In the prior art, such a centre tap has always required a multiple turn winding. A well-known example is a "bridge transformer" having a primary connected in first and opposite directions, in alternation, across a d.c. bulk voltage source, and a secondary winding having a centre tap connected to one side of the load, such as ground, and winding ends connected through respective diodes to the other side of the load to supply the same in push-push fashion. In high secondary current designs, it can be difficult to make the required connections to the secondary in a manner whereby they do not interfere mechanically or electrically with each other and wherein the diodes are packaged close to the secondary winding structure. In particular, the three connections exiting together from a conventional bridge transformer make it very difficult to contain the entire diode-diode commutate current loop within the transformer.

[0005] The invention seeks to provide an inductive device which enables a transformer to be made which does not suffer from the above described deficiencies of the prior art.

[0006] The invention provides an inductive device comprising an electrical conductor and a magnetic core wound more than once around the conductor.

[0007] A preferred application of the invention is a transformer consisting of an inductive device as defined in the preceding paragraph, the conductor around which the magnetic core is wound more than once serving as the secondary current path of the transformer and the device being provided with a primary current path to induce magnetic flux in the core.

[0008] In the extreme, the secondary current path consists of a single turn linked N times by the flux (φ) induced by action of the primary, so that the voltage induced in the secondary is a direct function of N_W(dN_Fφ/dt) instead of the familiar N_W(dφ/dt), where N_w = number of turns of the coil and N_F equals the number of turns of the flux.

[0009] How the invention can be carried out will now be described by way of example, with reference to the accompanying drawings, in which:

Fig. 1 is a schematic drawing of a transformer including a multi-turn magnetic core about a loop of conductor and associated circuit elements;

Fig. 2 is an exploded view of a transformer structure embodying electro magnetic principles shown and described with respect to Fig. 1 and further including a schematic showing of electrical components illustrative of a push-push output circuit which may be driven by the transformer;

Fig. 3 is an electrical diagram of a voltage regulator of a full-bridge kind which includes the transformer structure and circuit elements shown in Fig. 2, in a pulse-width modulated full-bridge input, push-push output topology.

Fig. 4 is a timing diagram containing idealized waveforms illustrative of the operation of the regulator of Fig. 3;

Fig. 5 illustrates an alternative configuration of the transformer of Fig. 2; and

Figs. 6 and 7 show a diode mount suitable for use in the structures of Figs. 2 and 5, Fig. 7 being a cross-section taken on line 7-7 of Fig. 6.

[0010] In high frequency operations, the cross-section of a transformer core is reduced compared with low frequency operation. However, in high current output circuits, the secondary winding of a transformer can be very thick and bulky. In a transformer embodying the invention, the core is wrapped around the secondary winding a plurality of times at least partly in lieu of the secondary winding being wrapped around the core a plurality of times. Fig. 1 shows this principle of operation. A voltage source 10 (V_in) is connected by a conductor 12 to a primary winding 14 of N1 turns wrapped around a portion of a shaped ferrite core 16. The magnetic core 16 has a plurality of turns 18 wrapped around a single turn secondary conductor 20, the output ends of which are connected via conductors 22 to a load 24 to deliver V_out thereto.

[0011] The voltage seen at the output 24 is V_out = (N2/N1) V_in, where N1 equals the number of turns in the primary winding 14 and N2 equals the number of turns 18 of the ferrite core around the single turn secondary "winding" 20.

[0012] If the secondary winding 20 were of a different number of turns N3 (not shown), V_out would equal N3 (N2/N1) V_in, N1 being the number of primary turns and N2 being the number of turns of the core around the secondary winding.

[0013] Fig. 2 is an exploded isometric view of a bridge transformer embodying the invention and using a two-turn core. Fig. 3 is an electrical and magnetic flux path diagram corresponding to the core and conductor arrangement of Fig. 2, and shows in addition, a full bridge drive circuit for the primary winding thereof. The rectifiers 110, 112, the output filter inductor 114, the capacitor 116, and the load 118 are all conventional output circuit elements insofar as their electrical function is concerned. The primary circuit, not shown in Fig. 2, could be a full bridge as in Fig. 3 or some other suitable circuit for symmetric drive.

[0014] The core elements 120, 122, 124, 126 of Fig. 2, when assembled, form a single closed flux path (128, Fig. 3) which threads the secondary conductor loop 130 twice. The secondary conductor loop 130 encloses two core posts 152 and 156, excludes two core posts 154 and 158, and is in one plane. It connects to the output circuit through the rectifiers 110, 112 at one end, and through the centre tap connection 132 at the other end. The rectifiers 110, 112 make contact with the bottom of conductor loop 130 at the areas indicated by the dotted circles at 172, 174. The other rectifier contact is to conductor 178, which provides a bus connection to the external circuit. The details and advantages of this rectifier arrangement are described later. The primary winding 140 encloses the same core posts 152 and 156 as the secondary loop 130, and is of the same general shape as the secondary conductor 130. The winding 140 may be formed in pancake style, one conductor thick. The core elements 120, 122, 124, 126 mate at their core post faces to form a single continuous zig-zag shaped flux path twice linking the secondary 130 and providing a window to receive and link the primary winding 140.

[0015] Fig. 3 illustrates the operation of the structure of Fig. 2 in a full bridge driven, pulse width modulated, push-push output power supply. To simplify the figure, the entire flux path is represented by the line 128. A pulse width modulating (PWM) control 210 operates first and second pairs of transistor switches 212, 214 and 216, 218 to conduct alternately, first one pair and then the other. A bulk DC supply VB is connected via the first pair of transistor switches 212, 214 to pass, when 212 and 214 conduct, primary current I1, through the primary winding 140. This sets up flux φ, in core turn A, and in core turn B in series therewith, thereby inducing a voltage V1 in each half of secondary 130, resulting in a current I3 in one half through diode 110.

[0016] A sense line 220 connects the output terminals at the load 118 to the PWM control 210. The PWM control can be any of many well-known kinds, such as free-running (demand) or oscillator driven, and will usually include a reference for comparison to the output voltage sensed via line 220. In any event, after a short (pulse) period, PWM control 210 turns the first pair of switches 212, 214 OFF and after a controlled delay turns the second pair 216, 218 ON to deliver a second current pulse I2 to the primary winding 140, in the direction opposite to that of the first current I1. This sets up flux φ2 in both core turns A and B of the magnetic circuit (defined by the core elements 120, 122, 124, 126 of the structure shown in Fig. 2). The increase of flux φ2 induces potentials V2 in both half turns of secondary 130. Diode 110 blocks one side but I4 flows in the other side, through diode 112 to the filter and load circuit elements 114, 116, 118.

[0017] Fig. 4 represents a typical timing diagram with idealized waveforms illustrative of the aforedescribed operation of the circuit of Fig. 3.

[0018] Fig. 5 shows a variation of the embodiment of Fig. 2, in which the primary winding consists of two separate coils 140′, one around each core post enclosed by the secondary conductor loop 130′. The coils 140′ may be wired in series or parallel to form the primary winding. In either case, they are preferably arranged such that their currents flow in the same sense, as shown for example by the clockwise arrows on the coils. The variation in Fig. 5 may provide more design flexibility compared with the structure in Fig. 2, but at the cost of increased leakage inductance.

[0019] In either bridge transformer variation, the rectifiers (110 and 112 in Fig. 2 or 110′ and 112′ in Fig. 5) may be mounted and connected conventionally, exterior to the transformer, or may be incorporated into the transformer. Incorporating them into the transformer allows the entire diode-diode commutate current loop to be constructed so that its geometry approximately matches the geometry of the primary winding current paths. This geometric match, combined with the close proximity of the primary coil(s) to the secondary structure, allows the primary current to nearly cancel the effects of the secondary commutate current during switch transitions, thus minimizing commutate loop inductance and allowing fast commutate times for high frequency operation.

[0020] In the variant shown in Figs. 6 and 7 the diodes 110, 112 of Fig. 2 (or 110′, 112′ of Fig. 5) are implemented as single chip devices in a package 150 received in the end portions 172, 174, 172′, 174′ of the secondary conductor loop 130 or 130′, so as to reduce inductance of the diode to diode commutate current loop. The package includes a compliant conductive member 176 which holds the diode chip in contact with the respective conductor 178 or 178′ by which the end portions 172, 174 or 172′, 174′ are connected to the external circuit. Further description of this kind of diode mount is given in an article entitled "Low Inductance Chip Connector for Power Rectifiers" published in the IBM Technical Disclosure Bulletin, Vol. 29, No. 3 (August, 1986) pages 1071-1072.

[0021] In either case, the bridge transformer embodies a two-turn core structure and associated "windings" which function as a magnetically tightly coupled power transformer suitable for inclusion in a switched mode power supply with a bridge type primary switch circuit. The transformer provides the conventional electrical terminals for such a circuit: two primary winding connections and three secondary connections (two "ends" and one centre tap). Electrically, the function is equivalent to the function of a conventional power transformer in this application. However, the internal structure of the transformer is such that the secondary winding is mechanically very simple, while the core forms a magnetic flux path (turn A, turn B) which twice threads the secondary winding 130 or 130′.

[0022] The magnetic core elements of Figs. 2, 3 and 5 are easily fabricated from ferrite or laminated iron or other suitable material, and can be made and mounted with tolerances whereby little or no gap occurs in the magnetic circuit, while the secondary 130 or 130′, being of one piece, has no joints to introduce electrical resistance.

[0023] It will be seen that the various embodiments of the invention described in detail above employ the principle of a flux path having plural loops in series about a conductor structure. While voltage step-down transformers have been discussed in particular, the primary and secondary designations could be reversed to provide voltage step-up.

Claims

1. An inductive electrical device comprising an electrical conductor (20) and a magnetic core (16) wound more than once around the conductor.

2. A transformer consisting of a device as claimed in claim 1, the conductor around which the magnetic core is wound more than once serving as the secondary current path of the transformer and the device being provided with a primary current path to induce magnetic flux in the core.

3. A transformer as claimed in claim 2, in which the primary current path consists of an electrical winding around the magnetic core.

4. A transformer as claimed in claim 2, in which the magnetic core is wound more than once around the primary current path.

5. A transformer as claimed in claim 3, in which the magnetic core is made up of four post segments (152, 154, 156 and 158) and four link segments (120, 122, 124 and 126), arranged to form a single continuous flux path, the segments being arranged so that the flux path comprises, in order, a first post (156), a first link (126), a second post (154), a second link (122), a third post (152), a third link (120), a fourth post (158) and a fourth link (124); and in which the secondary current path is connected to an external circuit via a pair of secondary terminals (172, 174), the secondary current path passing from one (172) of the pair of secondary terminals over the first link (126), under the second link (122), over the third link (120) and under the fourth link (124) to the other one (174) of the pair of secondary terminals, thereby enclosing the first (156) and third (152) of the four posts and excluding the second (154) and fourth (158) posts.

6. A transformer as claimed in claim 5, in which a third secondary terminal (132) is located on the secondary current path between the second post (154) and the fourth post (158), the third secondary terminal providing a centre tap connection to an external circuit.

7. A transformer as claimed in claim 5 or claim 6, in which each of the primary and secondary current paths is substantially planar.

8. A transformer as claimed in claim 7, in which the primary current path is a planar winding, and the secondary current path is formed from a single conducting sheet.

9. A transformer as in claimed any of claims 5 to 8, in which the primary current path and the secondary current path are of substantially identical shape and are positioned in close physical proximity to provide tight magnetic coupling.

10. An arrangement including a transformer as claimed in any of claims 5 to 9, and in which planar rectifier diode components are included within the secondary current path whereby inductance in the circuit loop formed by the secondary current path is minimized and commutating action of the diodes is facilitated.

Drawing