RU174405U1 - INDUCTIVE DEVICE - Google Patents

Abstract

The essence of the preferred embodiment of the claimed technical solution is as follows. A series of inductive devices designed for the rated input voltage has been developed, the values of which lie in the range from Umin to 9 * Umin, operating at instantaneous current values lying in the range from Imin to 2 * Imin. They use transformers with a primary winding, consisting of two windings, and the same current transformers with a nominal value of the primary current flow, lying in the range from Imin to 2 * Imin. The circuit board topology is designed only for these inductive elements. To transfer energy, the inductive device is tuned to the input voltage value by connecting the transformer windings in series for high voltages or in parallel for low voltages of the specified range. The adjustment is carried out by conductive elements, usually made in the form of metal jumpers. To transmit information about the instantaneous values of the current flowing through the transformer, these windings are connected by jumpers to the primary winding of the current transformer. When the windings of the transformer primary winding are connected in series through the current transformer, all the input current flows. When the windings of the transformer primary winding are connected in parallel, approximately half of the input current flows through the current transformer.

Description

The utility model relates to electronics and electrical engineering and can be used in feedback electronic devices, in particular in electronic devices with galvanic isolation of the energy transmission circuit and the information signal transmission circuit.

Further in the text, the terms relating to the transformer windings, defined in accordance with GOST 16110-82, are used. “Power transformers. Terms and Definitions". References to the term are given in the form: (item number according to GOST).

Known inductive devices for transmitting energy and information signals, used, for example, in secondary power sources (VIP) with galvanic isolation. In these inductive devices, energy is transferred by a transformer (hereinafter referred to as TP) from the primary to the secondary side of the VIP. The information signal about the instantaneous current value is determined using a current transformer (hereinafter referred to as CT), connected by the primary winding in series with the primary winding (4.5) TP, and from the secondary winding of the CT is transmitted, for example, to the VIP control circuit. If the CT is connected in series with the secondary winding TP (4.6), then the information signal from the CT is transmitted, for example, to the parallel VIP control circuit.

TP and TT are located and fixed in any known manner on the printed circuit board of the product, which uses an inductive device. For example, the main windings (4.3.) Of a planar TP are integrated into the printed circuit board, and the CT is mounted on one side of the printed circuit board, for example, by soldering.

In general, a CT can be connected at one end of its primary winding to an external circuit, and at the other end it can be connected to either the first or last turn of the main (primary or secondary) winding of the TR.

To control the current in the TP circuit, a CT can be used, the primary winding of which is part of the electrical circuit at the point of direct connection with the first or last turn of the main winding of the TR.

It is possible that the primary winding of the CT is used as part of the external circuit in the place of direct connection with the first or last turn of the main winding of the TR.

In general, energy can be transferred by any type of transformer, such as a current transformer.

Further, for simplicity of understanding the essence of the claimed utility model, a transformer transmitting energy will be considered only as a transformer that converts voltage.

The disadvantage of such inductive devices is that for different values of the nominal input voltage, it is required to use different power and dimensions TP and TT, as well as for each product designed for a certain rated voltage, to calculate and manufacture printed circuit boards with different mounting locations for the components of the inductive devices. With this approach to product development, it is impossible to unify the assembly process of commercially available products using such an inductive device. This leads to an increase in the complexity and duration of manufacture, since it is necessary to re-equip the equipment for assembling the product, designed for a different nominal input voltage.

Known configurable transformer with open windings (Patent US 6590488 "Configurable transformers, priority date 01/12/1999), including a primary winding consisting of m windings having Ni turns, where i is an integer between 1 and a certain integer n; while m and Ni are integers. The windings are connected by conductive jumpers located on the printed circuit board. The use of such a transformer allows the part of the inductive device transmitting energy to be unified for a wide range of nominal values of the input voltage.

But for measuring various instantaneous current values, it is still necessary to use CTs of different power. This leads to an increase in the complexity of manufacturing products designed for different nominal voltages, which use an inductive device with different overall dimensions of CTs and printed circuit boards with different topologies. For example, a current transformer manufactured by TDK-Epcos, designed for 20A, has dimensions of 8 × 7 × 5 mm (https://en.tdk.eu/download/1322408/bd3e374220e189cdab8da280fa5f2032/current-sense-transformers-5-0- inside-view.pdf), and at 40A - already 14 × 13 × 10 mm (https://en.tdk.eu/download/1322432/a478b1236c4b84e8bffda527fbce5044/current-sense-transformers-12-6-inside-view.pdf )

A current sensor is known (RF patent No. 2026558, IPC 6, G01R 19/00, priority from 11/22/1990), in which the primary winding of the CT is connected in parallel with the section of the conductor with the measured current. In this case, the amount of current flowing through the CT primary winding depends on the resistance value of the CT primary winding and the resistance of the section of the conductor with the measured current. Thus, the problem of using low-power CTs for measuring high currents is solved.

The disadvantage of this solution is the low resistance of the CT primary winding and the section of the conductor with the measured current, which necessitates a signal amplifier for measuring small (up to 0.1 A) currents. Such amplifiers are sensitive to changes in external, for example, temperature influences and require space for placement in the VIP structure, which increases its dimensions.

The objective of the technical solution is to create an inductive device that can operate at different nominal values of the instantaneous current without changing the design characteristics of the transformer and current transformer and the topology of the printed circuit board, only by changing the circuit of their connection.

The technical result is achieved in an inductive device comprising: a current transformer connected to a printed circuit board, including a primary winding and a secondary winding; a transformer comprising the main windings, at least one of the main windings includes at least two windings with input and output turns made with the possibility of their connection by conductive elements, the primary winding of the current transformer included between the turns of these windings.

In a preferred embodiment, the primary winding of the current transformer is connected between the output turn of the first winding and the input turn of the second winding of the main winding of the transformer.

In a preferred embodiment, the primary winding of the current transformer is connected between the input turn of the first winding and the input turn of the second winding of the main winding of the transformer, and the output turns of these windings are connected by a conductive element.

In a preferred embodiment, the primary winding of the current transformer is connected between the output winding of the first winding and the output winding of the second winding of the main transformer winding, and the input turns of these windings are connected by a conductive element.

In another embodiment, the primary winding of a current transformer, rigidly mounted on a printed circuit board, is configured to connect conductive elements to the input turns of the first and second windings of the transformer main winding, the output turns of which are connected by a conductive element.

In another embodiment, the primary winding of a current transformer, rigidly mounted on a printed circuit board, is configured to connect conductive elements to the output turns of the first and second windings of the transformer main winding, the input turns of which are connected by a conductive element.

A variant is possible in which at least one main winding of the transformer is made of more than two windings, the output turns of these windings are connected by a conductive connection, and the primary CT winding is connected with one input part to one part of the input turns of the transformer windings, and the output turn is connected to other part of the input turns of the transformer windings so that the instantaneous value of the current flowing through the primary winding of the current transformer is less than or equal to the value of the rated primary current current sformatora.

For simplicity of showing the essence of the claimed utility model, secondary windings are not shown in the images.

In FIG. 1 shows options for series connection of a current transformer with two windings of the main primary winding connected in series. The windings are connected to the pads (dark squares). Between themselves, the contact pads are connected by jumpers (bold lines).

In FIG. 1a shows a preferred embodiment of an inductive device. In this embodiment, the primary winding of a current transformer is used instead of a conductive element.

In FIG. 1b shows an embodiment of an inductive device in which a current transformer is rigidly mounted on a printed circuit board. Its connection with series-connected transformer windings is carried out by conductive elements.

In FIG. 2 shows options for series connection of a current transformer from one of the parallel windings of the primary main winding. The windings are connected to the pads (dark squares). Between themselves, the contact pads are connected by jumpers (bold lines).

In FIG. 2a shows a preferred embodiment of an inductive device in which the primary winding of a current transformer is used instead of a conductive connection.

In FIG. 2b shows an embodiment of an inductive device in which a current transformer is rigidly mounted on a printed circuit board. Its connection with parallel connected transformer windings is carried out by conductive elements.

In FIG. 3 shows a preferred embodiment of an inductive device for three windings of the primary primary winding connected in parallel.

In accordance with the above described embodiments (Figs. 1 and 2), the transformer (T1) contains a primary primary winding consisting of two windings with terminals 1.1, 1.2, 1.3, 1.4, and the current transformer (T2) contains a primary winding.

For a current transformer with a primary primary current rating equal to or greater than the input current of the inductive device, either one primary winding (not shown) or the design of the inductive device shown in FIG. 1a and b, where the primary winding of the current transformer is connected in series with the windings of the transformer.

For embodiments of the preferred embodiment of the inductive device shown in FIG. 2a and 2b, the primary winding of the current transformer T2 with a nominal value of the primary through current below the input current is connected in series with one winding and in parallel with the other transformer winding.

The findings of the windings in series and parallel connection of the windings are connected by conductive elements (jumpers).

When automatically assembling the preferred product variant, only the program for placing jumpers and / or the length of the jumpers needs to be changed.

The essence of the preferred embodiment of the claimed technical solution is as follows. A series of inductive devices designed for the rated input voltage has been developed, the values of which lie in the range from U _nom min to 9 * U _nom min, operating at instantaneous current values lying in the range from I _im min to 2 * I _mi min. They use transformers with a primary winding, consisting of two windings, and the same current transformers with a nominal value of the primary feed current, lying in the range from I _im min to 2 * I _im min. The circuit board topology is designed only for these inductive elements.

To transfer energy, the inductive device is tuned to the input voltage value by connecting the transformer windings in series for high voltages or in parallel for low voltages of the specified range. The adjustment is carried out by conductive elements, usually made in the form of metal jumpers. To transmit information about the instantaneous values of the current flowing through the transformer, these windings are connected by jumpers to the primary winding of the current transformer.

When the windings of the transformer primary winding are connected in series through the current transformer, the entire input current flowing in the device circuit is transmitted.

When the windings of the transformer primary winding are connected in parallel through the current transformer, approximately half of the input current flowing in the circuit of the device goes.

Alternatively, a current transformer can be used in place of one of the jumpers connecting the transformer windings. In this case, when developing a printed circuit board, it will be necessary to form the contact pads of the terminals of the voltage transformer windings with the ability to install both jumpers and the primary CT winding on them for switching the TP windings. When assembling this option, you will need to replace only one cassette with jumpers on current transformers.

All arguments and conclusions relating to this design option of the inductive device apply to all similar options: when using more than two windings; when using windings on the secondary side of the transformer; when using one winding made of parallel-connected conductors, both located parallel to each other, and twisted into a bundle.

Structurally, voltage and current transformers can be: winding or planar products located on the surface of the printed circuit board or integrated into it.

For an overhead, immersed, or hybrid planar transformer design, the current transformer can be located on either side of a multilayer printed circuit board with transformer windings, or on the main board of the product that uses an inductive device.

Claims (6)

1. Inductive device comprising connected to a printed circuit board: a transformer with main windings, and at least one of the main windings includes at least two windings with input and output turns made with the possibility of their connection by conductive elements with each other and with input and output turns of the primary winding of the current transformer, characterized in that the primary winding of the current transformer is connected between the turns of the windings of the main winding of the transformer. 2. The inductive device according to claim 1, characterized in that the input and output turns of the primary winding of the current transformer, rigidly mounted on the printed circuit board, are configured to connect conductive elements to the input and output turns of the windings of the main transformer winding. 3. The inductive device according to claim 1, characterized in that the primary winding of the current transformer is connected by conductive elements to the input turns of the first and second windings of the main transformer winding, and the output turns of these windings are connected by a conductive element. 4. The inductive device according to claim 1, characterized in that the primary winding of the current transformer is connected by conductive elements to the output turns of the first and second windings of the main transformer winding, and the input turns of these windings are connected by a conductive element. 5. The inductive device according to claim 1, characterized in that the primary winding of the current transformer is used as one of the conductive connections between the two windings of the main winding of the transformer. 6. The inductive device according to claim 1, characterized in that at least one main winding of the transformer is made of more than two windings, the output turns of these windings are connected by a conductive connection, and the primary CT winding is connected by an input turn to one part of the input turns of the transformer windings, and the output coil is connected to another part of the input turns of the transformer windings so that the instantaneous value of the current flowing through the primary winding of the current transformer is less than or equal to the value of the nominal flow between primary current transformer.

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