JPH03212134A - Power supply system - Google Patents

Abstract

PURPOSE:To reduce the size and weight of a system by inverting a DC output from a converter after rectifying and smoothing an AC source voltage to an AC voltage having a desired frequency by a controller and a switching element. CONSTITUTION:An AC voltage from a commercial AC power source 1 is input to an AC/DC converter 4, rectified, smoothed by a diode bridge 2 and a smoothing capacitor 3, and converted to a DC voltage. The DC voltage is continuously intermittently varied by a switching element 5 to be controlled by a controller 6, inverted to an AC voltage having a desired frequency, and applied to a primary winding 7a. Accordingly, it is inverted to a voltage having a high frequency to reduce the size and weight. a current is induced in a secondary winding 7b, rectified by rectifying diodes 10, 11, smoothed by an LC filter and supplied to a load 14.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a power supply system that supplies power by electromagnetic induction.

[Prior Art] FIG. 5 is a perspective view showing a conventional electrical outlet that is commonly used. In the figure, (15) is the outlet body, (16) is the outlet provided on the outlet body (15), (17) is the outlet cap, (
18) is an insertion piece provided on the outlet cap (17).

The conventional outlet shown in Figure 5 has a socket (16).
Electrical connections are made by inserting the insert piece (18) into the metal surface and making contact with the metal surface, but poor contact is likely to occur due to poor contact pressure or oxidation of the contact surface, and the insert piece (18) must be insulated. Therefore, there is a risk of electric shock by touching the plug-in piece (18) that is about to come loose from the plug-in port (1B). In addition, underwater where there is a risk of electrical leakage,
There are problems such as it cannot be used in bathrooms, ship decks, swimming pools, etc.

Therefore, in order to solve this problem, electromagnetic outlets that do not have metal contact parts are being considered. FIG. 6 is a sectional view showing the structure of an electromagnetic outlet disclosed in Japanese Utility Model Application Publication No. 57-31818, and the same reference numerals as in FIG.
or a corresponding portion, (1) is a commercial AC power supply, (7a)
is the primary winding of the transformer, (7b) is the secondary winding of the transformer, (19a) is the primary core of the transformer, and (19b) is the secondary core of the transformer.

The electromagnetic outlet shown in Figure 6 has an outlet body (1
By applying an AC voltage from a commercial AC power supply (1) to the primary winding (7a) of the transformer configured in 5), -
The secondary iron core (19a) is magnetized, and the secondary iron core (19a) and the outlet cap (17) are configured as follows.
19b), this magnetic flux causes electromagnetic induction, current flows through the secondary winding (7a), and the load (14
). Since this electromagnetic outlet does not have a metal surface contact between the outlet body (15) and the outlet cap (17), problems such as poor contact, electric shock, and leakage can be solved.

[Problems to be Solved by the Invention] Conventional power supply systems are configured as described above, and problems such as poor contact, electric shock, and leakage can be solved; however, commercial AC power is directly applied to the primary winding of the transformer. The configuration requires a large and heavy transformer corresponding to the commercial frequency, resulting in an increase in the size of the device. Therefore, when installing a transformer on a wall, floor, ceiling, etc., the convex portion protrudes greatly and becomes a hindrance.

Additionally, embedding transformers in walls, floors, ceilings, etc. requires extensive construction work. Furthermore, the secondary iron core and secondary winding are large and heavy, making them difficult to attach and detach.
This becomes even more noticeable as the load increases.

Furthermore, there were other problems such as the inability to use it as a DC power source.

The present invention was made to solve this problem, and aims to provide a power supply system that can be made smaller and lighter and can also be used as a DC power source.

[Means for Solving the Problems] A power supply system according to the present invention includes an AC/DC converter that rectifies and smooths an AC power source to convert it into a DC, and a control circuit and a switching element that can arbitrarily convert the DC output from the converter. and conversion means for converting the frequency into alternating current.

[Function] In the present invention, a high frequency alternating current voltage can be applied to the transformer constituting the power supply system regardless of the power source, so the transformer used can be made smaller and lighter.

[Embodiments] Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1st
The figure is a circuit diagram showing one embodiment of the present invention. Note that the same or equivalent parts as in the conventional example shown in FIGS. 5 and 6 are denoted by the same reference numerals, and the explanation thereof will be omitted.

In the figure, (2) is a diode bridge for rectification, (
3) is a smoothing capacitor, (4) is an AC/DC converter, (
5) is a switching element that turns on and off the DC voltage output from the AC/DC converter (4) and converts it into an AC voltage of an arbitrary frequency. (6) is a control circuit that controls the switching element (5). (7) is a transformer, and (7e) is a snubber for initializing the transformer (A).
(8) is a snubber diode, (9) is a transformer isolation section, (10) and (11) are rectifier diodes, (12) is a choke coil, and (13) is a smoothing capacitor.

The power supply system in this embodiment is configured as shown in Fig. 1, and the AC voltage from the commercial AC power supply (1) is
It is input to the DC converter (4), and the diode bridge (2
) and a smoothing capacitor (3), the voltage is rectified and smoothed and converted into a DC voltage. This DC voltage is applied to the control circuit (6
) is continuously turned on and off by a switching element (5) controlled by a switching element (5), converted into alternating current of a desired frequency, and applied to the primary winding (7a).

Therefore, by converting to a higher frequency, a transformer (
7) can be made smaller and lighter. Then, the -order iron core is magnetized and a magnetic flux is formed between the primary iron core and the secondary iron core, and this magnetic flux causes electromagnetic induction, and the secondary winding (
A current flows through 7b). This current is rectified by rectifying diodes (lO) and (11) on the secondary side, smoothed by an LC filter consisting of a choke coil (12) and a smoothing capacitor (13), and converted into DC to the load ( 14).

Note that the snubber winding (7C) of the transformer (7) is connected to the snubber winding (7C) of the transformer (7) when the switching element (5) is open.
), and the transformer (7) is initialized by being regenerated to the smoothing capacitor (3) stored in the transformer (7) through the snubber diode (8).

Although Figure 1 shows a forward converter type power supply system, it is also possible to use a transformer as an outlet and a switching regulator, such as a push-pull type, half-bridge type, full-bridge type, flyback type, etc. Often, the rectifying and smoothing circuit on the secondary side of the transformer (7) may be omitted to obtain an AC output.

FIG. 2 is a circuit diagram showing another embodiment of the invention. In this embodiment, an LC filter section consisting of a choke coil (12) and a smoothing capacitor (13) is provided inside the load (14) outside the output terminal to make the outlet cap (plug) smaller and lighter. There is something.

The examples shown in Figures 1 and 2 show the case where a commercial AC power source (1) is input, rectified and smoothed by a diode bridge (2) and a smoothing capacitor (3), and converted to DC. However, other AC power sources or other rectifier circuits may be used. Also, by omitting the AC/DC converter (4),
For example, a DC power source such as a battery can also be used.

Figure 3 is a circuit diagram showing the state in which the primary and secondary sides of IJ1 are molded with insulating material, and Figure 4 is a circuit diagram showing the state in which the primary and secondary sides of Figure 2 are molded with insulating material. It is a connection diagram.

In FIGS. 3 and 4, (15) is an electromagnetic outlet formed as a separate transformer.

(16) is an integrated outlet body, which includes a primary winding (7a) wound around the negative side iron core and the primary side iron core, a snubber winding (7C), a snubber diode (8), and a control circuit. (
6) The switching element and the AC/DC converter (4) are entirely integrated with an insulating member and covered by molding. Integrated outlet body (
The fitting part (18a) of 1B) is formed in a concave shape and covered by molding.

(17) is an integrated outlet cap, which includes a secondary iron core, a secondary winding (7b) wound around the secondary iron core, rectifier diodes (10), (11), and a choke coil (12).
) and the smoothing capacitor (13) are integrated with an insulating member and covered by molding. In addition, the fitting part (17) of the integrated outlet cap (17)
A) is formed into a convex shape and covered by molding.

In this way, the concave fitting part (L) of the outlet body (1B)
ea) and the convex fitting part (1) of the outlet cap (17)
7a) are mechanically connected to each other in a fitted state, and an electrical connection is made by magnetic coupling, but since these are covered with an insulating member, for example, these can be removed using water in a bathtub etc. There is no risk of electric shock or leakage even if moisture adheres to the connecting parts.

In addition, since the outlet body (16) is integrated, the wiring of the cable connected to the outlet body (IB) is minimized, and the inductance component of the wiring due to the cable is almost eliminated, and the voltage drop due to the inductance component is significantly reduced. It is possible to increase the efficiency of the power supply and obtain the desired voltage according to the design.

Furthermore, by integrating the outlet body (16), handling becomes convenient and the installation location can be completed in one place.

[Effects of the Invention] As explained above, the present invention enables high-frequency alternating current voltage to be applied to a transformer that constitutes the power supply system regardless of the power source in a power supply system that supplies power by electromagnetic induction. This makes it possible to reduce the size and weight of the transformer used, which solves the problems of poor contact, electric shock, and leakage, making it possible to safely supply power in locations exposed to water or outdoors.

Furthermore, it is possible to obtain a power supply system in which the work for installing the outlet body is easy, the outlet cap (plug) can be easily attached and detached, and the power supply system can be used not only for AC input but also for DC input. I can do it.

[Brief explanation of drawings]

Fig. 1 is a circuit diagram showing one embodiment of the present invention, Fig. 2 is a circuit diagram showing another embodiment of the invention, and Fig. 3 is a molding of the primary side and secondary side of Fig. 1 with an insulating material. A circuit diagram showing a molded state, Fig. 4 is a connection diagram showing a state in which the primary side and secondary side of Fig. 2 are molded with insulating material, Fig. 5 is a perspective view showing a conventional electrical outlet, and Fig. 6 1 is a sectional view showing the configuration of a conventional electromagnetic outlet. In the figure, (1) is a commercial AC power supply, (2) is a rectifying diode bridge, (3) is a smoothing capacitor, and (4) is a rectifying diode bridge.
is an AC/DC converter, (5) is a switching element, (6
) is the control circuit, (7) is the transformer, (7a) is the negative winding, (7b) is the secondary winding, (7C) is the snubber winding, (8
) is the snubber diode, (9) is the transformer isolation section, (
10), (11) are rectifier diodes, (12) are choke coils, (13) are smoothing capacitors, (14) are loads, (15) are electromagnetic sockets, (1B) are socket bodies, (lea) are sockets Body fitting part, (1
7) is an outlet cap, and (17a) is a fitting portion of the outlet cap. Note that the same reference numerals in each figure indicate the same or corresponding parts. Agent Muneharu Sasaki

Claims (1)

[Claims] In a power supply system that has a transformer in which an insulated primary side and a secondary side can be separated and supplies power by electromagnetic induction, if the primary power supply is an AC power supply, this AC power supply is An AC/DC converter that rectifies and smoothes to convert it into direct current, and this AC/DC converter.
If the DC output from the DC converter or the primary power source is a DC power source, it is equipped with a conversion means for converting this DC power source into an alternating current of any frequency using a control circuit and a switching element, and the converting means converts the high frequency A power supply system characterized by applying voltage to the primary side of the transformer after converting the voltage into alternating current.