KR20180083672A - Device for manufacturing of transformer - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing a reduced transformer using dielectric polarization. In particular, a dielectric and a ferroelectric are inserted and installed between winding layers of coils forming a transformer, and whether the dielectric and the ferroelectric are installed is accurately determined, thereby manufacturing a highly efficient transformer. The transformer is manufactured by winding the coils around a ferrite core, wherein the ferroelectric and a weak dielectric are alternately disposed and arranged between the wound coils. The apparatus further comprises: a camera capturing and reading images of the dielectric and the ferroelectric; a control unit analyzing the result obtained by the camera, and outputting a warning signal when either the dielectric or the ferroelectric is omitted; and an automatic error signal output unit continuously outputting a warning sound when the control unit outputs the warning signal.

Description

TECHNICAL FIELD [0001] The present invention relates to a device for manufacturing a reduced transformer using a dielectric polarization,

[0001] The present invention relates to an apparatus for manufacturing a reduced transformer using dielectric polarization, and in particular, a dielectric and a rigid dielectric are inserted between winding layers of a coil constituting a transformer, And a transformer for transforming the transformer into a transformer.

It is already well known that electric and electronic products used by many people are becoming smaller and lighter due to the development of the electronic industry these days.

Such electronic products are loaded with a transformer (transformer) to extract a desired voltage. The general structure of the transformer is shown in Patent Application No. 10-1998-0044223. As shown in FIG. 1 or 2, The integral transformer is formed by successively inserting the secondary side laminate 20 and the primary side winding body 40 from below into the center pillar 11a of the E-shaped core 11 constituting a part of the core assembly 10, The I-shaped core 12 is welded to the open end of the shaped core 11. The secondary side laminated body 20 is formed by sequentially stacking and winding a conductor 24 in a strip shape, a dielectric 25, a conductor 26 and a dielectric 27 in this order.

That is, it can be seen that the conductors and the dielectrics are properly alternately mounted. However, there is a problem that vortex generation and harmonic removal are not easy as one dielectric.

On the other hand, among the components constituting the electric and electronic products, the transformer which changes the power supplied from the outside to the size of the power according to the characteristics of the equipment occupies many sizes and weights, thereby reducing the size and weight of the electrical and electronic products There has been a limit to the degree.

3, the conventional miniaturized transformer 1 includes a ferrite core 2 in which a plurality of thin steel plates are laminated, and a ferrite core 2 in which a primary side power is supplied to one side of the ferrite core 2 Side winding (3) and a secondary-side winding (4) to which a power source-proportional power is applied, which is applied to the primary-side winding (3), which is one side of the ferrite core (2).

However, in the conventional miniaturized transformer 1 as described above, the ferrite core 2 and the ferrite core 2 are provided in order to prevent the coil hands of the primary winding and the secondary winding 3, A large size and a large weight are required.

Since the primary side winding 3 and the secondary side winding 4 for obtaining a desired power source due to resistance and inductance are wound around the outer side of the ferrite core 2, the size and weight of the secondary side winding 4 are increased by the thickness of the coil, There is a problem that the manufacturing cost is also increased.

In addition, there is a problem that the heat generation of the transformer is increased due to an increase in the number of swirls, which shortens the life of the transformer.

In order to solve the above problems, the present invention provides a transformer, which is smaller in size than a conventional transformer, and at the same time, a dielectric and a ferroelectric are inserted between the winding layers to maximize the insulation performance, and the polarization of the dielectric and the ferroelectric And it is an object of the present invention to provide a compact transformer that maximizes efficiency by minimizing generation of vortices.

As means for achieving the above object,

The present invention relates to a method of manufacturing a transformer by winding a coil on a ferrite core to fabricate a transformer, wherein a ferroelectric material and a weak dielectric material are alternately arranged and arranged between winding coils; A camera for photographing and reading the dielectric and the ferroelectric; A controller for analyzing a result of the camera and outputting an alarm signal if any one of the dielectric and the ferroelectric is missing; And an error signal automatic output unit 1000 that continuously outputs an alarm sound when the control unit outputs an alarm signal.

The automatic error signal output unit 1000 includes a power supply unit 1101 for applying a power supply signal by its own power supply; An error signal output unit 1102 for receiving a signal from the control unit and switching the power supply circuit; An oscillation transformer 1103 which is supplied with electricity when the power supply unit is turned on and outputs a boosted AC current; A relay operation switching unit 1108 connected to the output terminal of the oscillation transformer 1103 and turned on by electrical supply; A relay switch 1107 installed at an output terminal of the switching unit 1108 for generating a magnetic force and generating a magnetic force; A first circuit connection switch sw1 that performs a function of energizing the circuit while the iron wire is pulled by the relay switch 1107; An error signal output power switch sw2 for supplying power to the error signal output control unit 1140 and displaying an error signal when the relay wire is pulled by the relay switch 1107; A circuit-operating iron piece (1131) which contacts the first circuit connecting switch to turn on the power-source holding switch part; An error signal output control unit power connection iron piece 1132 designed to operate in conjunction with the circuit operation iron piece and to connect the power source to the error signal output control unit when the circuit breaker is turned on; The first circuit connection switch and the base end are connected to each other and the emitter end and the collector end are connected to the oscillation transformer 1103 and the relay operation switching part 1108. The operation of the relay operation switching part 1108 pulls the iron piece When the first circuit connection switch sw1 and the error signal output power switch sw2 are forcibly turned off at this time, the closed circuit is broken, And the relay switch 1108 is turned on to turn on the first circuit connection switch sw1 and the error signal output power switch sw2 so as to continuously output an error signal And a switching unit 1118 for maintenance.

In addition, the error signal automatic output unit 1000 is provided between the first circuit connection switch and the circuit breaker for inducing the first circuit connection switch and the circuit breaker to remain in the off state at all times A resilient spring 1133; The first circuit connection switch is provided at one end of the first circuit connection switch. When the first circuit connection switch is switched by pulling the wire for circuit operation at the time of operation of the relay switch, A permanent magnet 1134 for maintaining the state; And a control unit for controlling the operation of the error signal display unit by turning off the wire for the circuit operation and the wire for connecting the error signal output control unit when the user operates the alarm unit to stop the alarm signal operation, And a manual operation switch 1135 for stopping the output of the alarm signal so that the alarm signal is no longer output.

In addition, the number of stacked ferrite cores 11 having a high magnetic density is reduced to 1/2, so that the value of the inductance is about 1/2, and the primary side and the secondary side of the ferrite core 11 have a primary side The number of turns of the winding 12 and the secondary winding 13 is increased so that the resistance value is increased to about two times so that the voltage due to the resistance and the current becomes equal to the desired value.

As described above, according to the present invention, a dielectric and a ferroelectric material are interposed between winding layers provided for manufacturing a transformer to maximize insulation performance, and a small-sized transformer that maximizes efficiency by minimizing the generation of vortices due to the polarization of the dielectric material and the ferroelectric material. .

1 to 3 are schematic diagrams showing the construction of a conventional transformer.
4 is a schematic view of a reduced transformer applied to the present invention.
FIG. 5 is a detailed configuration diagram of a reduced transformer of the present invention, in which a weak dielectric and a ferroelectric are applied. FIG.
6 is a block diagram of a weak dielectric and ferroelectric verify circuit of a reduced transformer of the present invention.
7 is a circuit configuration diagram for an error situation notification of the present invention;
8 is an enlarged view of the main part of Fig.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention, and are not to be construed as limiting the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The terms used below are defined in consideration of the functions of the present invention, which may vary depending on the user, intention or custom of the operator. Therefore, the definition should be based on the contents throughout the present invention.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. The configuration is omitted as much as possible, and a functional configuration that should be additionally provided for the present invention is mainly described.

Those skilled in the art will readily understand the functions of the components that have been used in the prior art among the functional configurations that are not shown in the following description, The relationship between the elements and the components added for the present invention will also be clearly understood.

In order to efficiently explain the essential technical features of the present invention, the following embodiments properly modify the terms so that those skilled in the art can clearly understand the present invention, It is by no means limited.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are merely illustrative of the technical idea of the present invention in order to efficiently explain the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs. .

4 is a schematic view of a reduced transformer applied to the present invention.

FIG. 5 is a detailed configuration diagram of a reduced transformer of the present invention, in which a weak dielectric and a ferroelectric are applied. FIG.

6 is a block diagram of a weak dielectric and ferroelectric verify circuit of a reduced transformer of the present invention.

7 is a circuit configuration diagram for an error situation notification of the present invention;

Fig. 8 is an enlarged view of the main part of Fig. 7,

It is possible to reduce the number of the ferrite cores to be laminated while using the ferrite core 11 having a high magnetic density and using the G core type and to reduce the number of the primary windings Side winding 13 and the secondary winding 13 are wound around the primary winding 12 and the secondary winding 13 in order to prevent the impedance of the small transformer 10 from decreasing as the diameters of the primary winding 12 and the secondary winding 13 decrease, The number of turns of the primary side winding 12 and the secondary side winding 13 is increased to some extent so that the voltage due to the resistance and the current is equal to the desired value.

The operation state of the present invention constructed as described above will be described below.

The small transformer 10 of the present invention significantly reduces the number of ferrite cores stacked by about one half while using the ferrite core 11 having a high magnetic density as the G core type.

If the number of ferrite cores 11 stacked here is reduced, the value of the inductance L may be reduced and the induction magnetic force may be reduced. However, by using the ferrite core 11 of the G core type having a high magnetic density, A sufficient induction magnetic force proportional to the number of turns of the primary winding 12 wound on the primary side of the ferrite core 11 and the number of turns of the secondary winding 13 wound on the secondary side is transmitted to the ferrite core 11 The size can be reduced.

If the number of turns is proportionally increased while using the primary side winding 12 and the secondary side winding 13 as coils having a small diameter, it is possible to increase the number of turns as shown in the formula of 'N2 / N1 * input voltage = output voltage' The accurate voltage due to the ratio of the primary side turn number N1 to the secondary side turn number N2 can be transmitted to the secondary side.

And the secondary side power can be obtained by the formula of (input power - core hand + coil hand in the transformer).

The number of turns of the transformer 10 is reduced by decreasing the number of coils of the primary winding wire 12 and the secondary winding wire 13.

However, as the number of turns decreases, the impedance of the transformer decreases. Impedance = 2πfL * As can be seen from the formula of the internal resistance of the coil, a current larger than the intended purpose flows on the input side. To reduce this current, The internal resistance of the primary winding 12 and the secondary winding 13 may be small so that the internal resistance is appropriately increased.

That is, the diameters of the primary side winding 12 and the secondary side winding 13 are made small so that the internal resistance can be increased while obtaining a necessary impedance in association with the number of turns of the windings 12 and 13.

Therefore, it is possible to reduce the number of layers of the core 11 made of a material having a high magnetic density and increase the number of turns of the coils having small diameters in the primary winding 12 and the secondary winding 13, The size and weight of the ferrite core 11 and the windings 12 and 13 are reduced, thereby enabling a small-sized transformer to be reduced in weight.

Further, a dielectric body and a ferroelectric material are inserted between the winding layers constituting the primary winding and the secondary winding, and a capacitor is inserted between the core and the coil.

On the other hand, the capacitor and the coil inductor must realize accurate resonance characteristics.

Generally, the resonant frequency is defined as in Equation 1 below,

.............식1

............. Equation 1

A desired resonance frequency can be obtained by controlling the L value and the C value in Equation (1).

However, when an inductor and a capacitor are used in combination for actual power supply devices and the like, the temperature and the L and C values of the inductor and the capacitor change due to an increase in frequency and a loss of the device, it's difficult.

However, in the present invention, accurate resonance characteristics are realized by controlling the L and C values of the inductor and the capacitor according to the temperature rise.

That is, the inductor element that implements the L value and the capacitor element that implements the C value rise in value to the specified temperature range when the temperature rises, reach the peak point, and then increase the temperature (Curie temperature) . Therefore, when manufacturing the planar inductor and the planar capacitor, it is possible to control the combination of the raw material and the manufacturing process so that the inductor and the capacitor minimize the change of the L and C values according to the temperature change in the actual operating temperature range, do. In addition, when the inductor and the capacitor are manufactured, the additive is added to control the peak temperature to be the same, and the sharp peak point is rounded and flattened to realize a constant resonance frequency by realizing a constant characteristic in the practical temperature range.

Therefore, in the present invention, the characteristic of the coil inductor and the capacitor and the temperature characteristic are adjusted by the composition of the magnetic core material and the dielectric material, the manufacturing method and the lamination method, and the accurate resonance characteristic is realized.

Further, since the dielectric and the ferroelectric are inserted between the winding layers, the dielectric and the ferroelectric are polarized when a voltage or an electric current flows through the coil, thereby suppressing vortex generation through the iron core and suppressing the generation of harmonics, .

Particularly, according to the present invention, a camera is used to photograph whether or not a dielectric and a ferroelectric provided between the winding layers are installed, and if a dielectric or ferroelectric is not installed, an error signal is output, Thereby inducing all of the ferroelectric elements to be installed.

That is, the camera captures the winding layer and outputs the result to the control unit. If the weak dielectric or the ferroelectric is not mounted, the control unit outputs a continuous alarm sound through the error signal automatic output unit 1000, .

The automatic error signal output unit 1000 includes a circuit power supply unit 1101, an error signal output unit 1102, an oscillation transformer 1103, a relay operation switching unit 1108, a relay switch 1107, A first circuit connection switch sw1, a communication terminal power switch sw2, and a power supply holding switch 1118. [

The power supply unit 1101 applies a power supply signal by itself.

The error signal output unit 1102 switches the power supply circuit when a control signal is output from the control unit.

The oscillation transformer 1103 is supplied with electricity when the power supply unit is turned on, and outputs the boosted AC current.

The switching unit 1108 for relay operation is connected to the output terminal of the oscillation transformer 1103 and is turned on by electrical supply.

The relay switch 1107 is installed at an output terminal of the relay operation switching unit 1108 and generates a magnetic force.

The first circuit connection switch (sw1) performs a function of energizing the circuit by pulling the iron wire by the relay switch (1107).

The power switch for outputting the error signal sw2 induces an error signal to be displayed by supplying power to the error signal output control unit 1140 while the iron strip is pulled by the relay switch 1107. [

The power supply switching unit 1118 is connected to the base end of the first circuit connection switch and the emitter end and the collector end are connected to the oscillation transformer 1103 and the relay operation switching unit 1108, The wire is pulled by the operation of the switch 1108 to form a closed circuit while switching is turned on, and then the operation of the relay switch 1107 is stopped. At this time, if the first circuit connecting switch sw1 and the error signal output power switch sw2 are forcibly turned off, the closed circuit is broken while the closed circuit is broken and the relay operating switch 1108 is turned on and the relay switch is turned on The first circuit connecting switch sw1 and the error signal output power switch sw2 are turned on to induce the error signal to be output continuously.

The present invention further includes a circuit element for operation 1131 and an alarm signal operation control unit power connecting piece 1132, a resilient spring 1133, a permanent magnet 1134, and a manual operation switch 1135 .

The circuit-operating piece 1131 contacts the first circuit connecting switch to turn on the power-supply holding switch portion.

The error signal output control unit power connecting conduit 1132 is designed to operate in conjunction with the circuit breaker. When the circuit breaker is turned on, the error signal output control unit is connected to the power source to induce the alarm apparatus to operate.

The elastic spring 1133 is provided between the first circuit connection switch and the circuit operation steel wire to guide the first circuit connection switch and the circuit operation wire to be kept in an off state at all times during non-operation.

The permanent magnet 1134 is installed at one end of the first circuit connection switch. When the first circuit connection switch is switched by pulling the wire for circuit operation at the time of operation of the relay switch, the circuit for operating the circuit is attached so that even if the operation of the relay switch is stopped The ON state of the switching unit for power supply maintenance is maintained.

The manual operation switch 1135 is coupled to a wire for circuit operation and a wire for connecting an error signal output control unit to the power supply. When the user operates the wire to stop the operation of the alarm signal, The operation of the error signal display unit is stopped so that the alarm signal is no longer output.

Hereinafter, the operation of the error signal automatic output unit 1000 will be described.

First, when the error signal output unit 1102 is turned on, a DC power source is connected to supply power to the oscillation transformer, and a high voltage is applied to the secondary side of the oscillation transformer.

The power source induced on the secondary side becomes a DC power source of a half wave through a rectifying diode, and this half wave DC power source becomes a more stable DC power source due to the charging and discharging action of the condenser.

This DC power source is applied to the anode terminal of the thyristor through the coil of the relay switch 1107, while the DC power source charges the capacitor through the resistor. The elevated voltage passes through the die and triggers the switching section 1108 for relay operation so that the node node and the cathode node are switched so that the operation of the relay switch is made, The circuit connection switch sw1 and the error signal output power switch sw2 are turned on to apply power to the error signal output control unit 1140 to display an error signal.

When the first circuit connection switch sw1 is activated, a base end of the power supply maintaining switch 1118 is activated, and a closed circuit is induced in the emitter end and the collector end of the power supply holding switch 1118 to supply power to the transformer Off.

That is, a voltage between the resistor 1109 and the capacitor 1110 flows through the diode 1120 to flow between the emitter terminal and the collector terminal of the power source holding switching unit 1118, and the resistance between the resistor by the bypass and the capacitor When the voltage between the resistor and the capacitor is lowered, the trigger signal to the switching unit for relay operation 1108 is stopped, so that the node end and the tail end are turned off and the current flows to the relay switch 1107 So that the power supply is continuously stopped for switching.

On the other hand, if the operator turns off the first circuit connecting switch and the error signal output power switch during the error signal output, there is no current flow in the closed circuit, and accordingly, the bias voltage flowing between the emitter end and the base end of the power- And the power supply switching unit 1118 is turned off.

The power supply switching unit 1118 is turned off to remove the bypass voltage between the resistor and the capacitor through the diode 1120 and the voltage is charged in the capacitor 1110.

The charged voltage causes a break-over phenomenon of the die 1111 and a trigger signal is output from the die to the switching section 1108 for auxiliary switch operation to move the iron piece, while maintaining the closed circuit, and at the same time, So that the error signal display unit 1150 can be continuously operated.

That is, according to the present invention, if an error factor is not cured, a warning sound is continuously output to guide the user to heal an error factor.

That is, even if the user turns off the alarm signal by operating the manual switch 1135 while the error signal output unit 1102 is in the on state, the alarm signal is automatically output by returning the power source again, It is possible to induce to completely shut off the error signal since it is restarted again even if the alarm signal is cut off.

If the error signal output section is turned off, the user can operate the manual switch 1135 to manually shut off the alarm signal.

10: Small transformer main body
11: Ferrite core
12: Primary winding
13: secondary winding
400: camera
500:
1000: Error signal automatic output section

Claims (4)

A transformer is manufactured by winding a coil on a ferrite core, wherein a ferroelectric and a weak dielectric are alternately arranged and arranged between winding coils;
A camera 400 for photographing and reading the dielectric and ferroelectric material;
A controller 500 for analyzing the result of the camera and outputting an alarm signal if any one of the dielectric and the ferroelectric is missing;
And an error signal automatic output unit (1000) for continuously outputting an alarm sound when the control unit outputs an alarm signal. The method according to claim 1,
The error signal automatic output unit 1000 outputs,
A power supply unit 1101 for applying a power supply signal by its own power supply;
An error signal output unit 1102 for receiving a signal from the control unit and switching the power supply circuit;
An oscillation transformer 1103 which is supplied with electricity when the power supply unit is turned on and outputs a boosted AC current;
A relay operation switching unit 1108 connected to the output terminal of the oscillation transformer 1103 and turned on by electrical supply;
A relay switch 1107 installed at an output terminal of the switching unit 1108 for generating a magnetic force and generating a magnetic force;
A first circuit connection switch sw1 that performs a function of energizing the circuit while the iron wire is pulled by the relay switch 1107;
An error signal output power switch sw2 for supplying power to the error signal output control unit 1140 and displaying an error signal when the relay wire is pulled by the relay switch 1107;
A circuit-operating iron piece (1131) which contacts the first circuit connecting switch to turn on the power-source holding switch part;
An error signal output control unit power connection iron piece 1132 designed to operate in conjunction with the circuit operation iron piece and to connect the power source to the error signal output control unit when the circuit breaker is turned on;
The first circuit connection switch and the base end are connected to each other and the emitter end and the collector end are connected to the oscillation transformer 1103 and the relay operation switching part 1108. The operation of the relay operation switching part 1108 pulls the iron piece When the first circuit connection switch sw1 and the error signal output power switch sw2 are forcibly turned off at this time, the closed circuit is broken, And the relay switch 1108 is turned on to turn on the first circuit connection switch sw1 and the error signal output power switch sw2 so as to continuously output an error signal And a switching unit (1118) for holding the dielectric transformer. 3. The method of claim 2,
The error signal automatic output unit 1000 outputs,
A resilient spring (1133) installed between the first circuit connection switch and the circuit operation iron piece to guide the first circuit connection switch and the circuit operation iron piece to be kept in an off state at all times during non-operation;
The first circuit connection switch is provided at one end of the first circuit connection switch. When the first circuit connection switch is switched by pulling the wire for circuit operation at the time of operation of the relay switch, A permanent magnet 1134 for maintaining the state;
And a control unit for controlling the operation of the error signal display unit by turning off the wire for the circuit operation and the wire for connecting the error signal output control unit when the user operates the alarm unit to stop the alarm signal operation, Further comprising a manual operation switch (1135) for stopping the output of the alarm signal so that no further alarm signal is output. The method according to claim 1,
The number of laminations of the ferrite core 11 having a high magnetic density is reduced to 1/2 so that the value of the inductance is about 1/2 and the primary side and the secondary side of the ferrite core 11 have primary- The number of turns of the secondary winding 13 and the number of turns of the secondary winding 13 is increased so that the resistance value is increased to about two times so that the voltage due to the resistance and the current becomes equal to the desired value. Device.

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