RU63133U1 - POWER SUPPLY - Google Patents

Abstract

The power supply includes a housing; a linear alternating current pulse generator with a fixed solenoid and a movable magnet installed with the possibility of shuttle movement along the channel passing inside the solenoid, between the end limiting elements located outside the solenoid; electronic means mounted on the periphery of the housing, outside the channel, a current rectifier and a charge storage device; electrical contact terminals for connecting the load. The technical result consists in reducing the axial dimension of the power supply, which expands the scope of its application.

Description

The utility model relates to the generation of electric energy, specifically, to the device of autonomous renewable current sources, more precisely, to low-power power supply units with a linear generator driven by an external action on the housing.

Known power supply unit, comprising a housing; a linear alternating current pulse generator with a fixed solenoid and a movable magnet, mounted with the possibility of shuttle movement along the channel passing inside the solenoid, between the end limiting elements located outside the solenoid; electronic devices with a rectifier and a charge storage; electrical contact terminals for connecting the load: see US patent No. 5347186, figa.

The specified device is an analogue and prototype of the proposed utility model. The known power supply unit includes an elongated housing, on one side of which a solenoid is placed (more precisely, a solenoid row of several inductive coils), and on the opposite side there are electronic means with electrical contact terminals for connecting the load (devices consuming electricity). This power supply unit has a large axial dimension, which does not allow it to be integrated into the enclosures of widely used consumer devices: portable radios, players, hand-held remote controls, etc.

The utility model solves the technical problem of reducing the axial dimension of the power supply in order to expand its scope.

The technical task is solved in that in the power supply unit, including the housing; a linear alternating current pulse generator with a fixed solenoid and a movable magnet installed with the possibility of shuttle movement along the channel passing inside the solenoid, between the end limiting elements located outside the solenoid; electronic devices with a rectifier and a charge storage; electrical contact terminals for connecting the load, according to a utility model, a current rectifier and a charge storage device are mounted on the periphery of the housing, outside the channel.

In special cases, the implementation of the utility model:

- a current rectifier and a charge storage device are mounted on one side of the solenoid;

- a current rectifier and a charge storage device are mounted on opposite sides of the solenoid;

- the charge storage device is an ionistor;

- the charge storage device is a battery;

- the charge storage device is a capacitor;

- the magnet has a cylindrical shape;

- the magnet has the shape of a rectangular parallelepiped;

- the end restrictive element is an elastic disk;

- the end restrictive element is an elastic diaphragm;

- the end restrictive element is a spring;

- the end restrictive element is a fixed magnet facing the movable magnet with the same pole;

- the end restrictive element is the end surface of the channel;

- the end restrictive element is the hull;

- the solenoid is made of 2000-5000 turns of copper wire with a diameter of 0.15-0.5 mm;

- the external transverse size of the solenoid exceeds the corresponding internal one by (1.5-2.5) times;

- the axial size of the solenoid is (0.75-1.25) the lengths of the magnet;

- the distance from the solenoid to the end of the restrictive element is (0.75-1.5) lengths of the magnet;

- the length of the magnet is (0.75-1.25) of the magnitude of its diameter;

- the power supply unit is configured to mount in the consumer device of electricity in place of regular power batteries;

- the casing of the power supply unit is equipped with bendable elements for securing electricity to the consumer device.

When implementing a utility model, a technical result is expected that coincides with the essence of the problem being solved.

The essence of the utility model is illustrated in FIGS. 1-8:

- FIG.1 is a schematic illustration of the proposed power supply, a plan view, with a partial section;

- FIG.2 is a cross section along aa of the power supply unit shown in FIG.1;

- FIG.3 is a cross-section along BB of the power supply unit shown in FIG.1;

- FIG. 4 is a plan view of a television receiver remote control with a built-in power supply unit;

- FIG. 5 is a plan view of another remote control of a television receiver with a built-in power supply unit;

- FIG.6 is a right view of the remote control of FIG.5, with a partial section along CC;

- FIG.7 is a top view of the remote control of FIG.5, with a partial section along the D-D;

- FIG.8 is a top view of the remote control of FIG.5, with a partial section along EE.

The proposed power supply unit shown in FIGS. 1-3 includes a plastic case (shell) 1 in the form of a rectangular parallelepiped with rounded edges. A rectangular tube 2 of non-magnetic, electrical insulating material (usually plastic) is mounted in the casing. The tube is covered in the middle part by a solenoid (inductive coil) 3, and inside the tube there is a rectangular magnet 4, rectangular in cross section, placed with a gap for the possibility of shuttle movement in the tubular channel, between the restrictive elements installed at its ends - elastic disks 5 and 6.

The solenoid together with the tube and magnet form a linear alternating current pulse generator. The movement of the magnet relative to the solenoid necessary for their generation is carried out by force acting on the body of the power supply unit: manual shaking, vibrations when walking (running) or when the vehicle (bicycle, car) is moving, etc. In this case, the end restrictive elements 5 and 6 dampen the impact of the magnet on the design of the power supply unit, and also facilitate the return movement of the magnet in the direction of the solenoid.

The current pulses generated in the solenoid are supplied to the electronic means (in the electronic circuit) of the power supply unit, which include a rectifier

current (for example, the well-known 4-diode bridge) and an electric charge storage device (battery, ionistor, capacitor). They are mounted in cavity 1A at the periphery of the housing, outside the tubular channel. To connect the load, the power supply unit is equipped with electrical terminals 7 and 8.

The indicated location of the current rectifier and charge accumulator, the possibility of which is due to the excess of the transverse dimension of the solenoid over the size of the tubular channel, reduces the axial size of the power supply unit, making it convenient to fit it into the design of various widely used consumer devices.

As an example, FIG. 4 shows the described power supply unit as part of a hand-held remote control for a television receiver, designed to be powered by standard batteries. A 3-volt power supply unit is installed in the recess of the console 9, in place of a standard pair of cylindrical 1.5-volt batteries 10, 11 (indicated by strokes). For the convenience of such a replacement, the terminals 12, 13 of the power supply unit are made the same as those of the battery pair. The cover for the power supply unit may differ in geometric shape from the cover for batteries and, if necessary, may be equipped with brackets and other retaining elements.

FIGS. 5-8 show another remote control of the television receiver with the proposed power supply installed instead of standard batteries (or batteries). Here, in contrast to FIGS. 1-4, the power supply unit is placed across, and not along the console 14, and the housing 15 of this unit has a stepped shape, due to the size of the battery niche. By its dimensions, the power supply unit extends beyond the console and is attached to it by means of bendable elements provided on the block body - two rows of flexible brackets 16A, 16B. The block body completely covers a niche, without the need for a separate cover. The current rectifier and the electric charge storage device are mounted in two similar cavities 17 and 18, respectively, which are located on opposite sides of the solenoid 3. The remote control is connected to the terminals 19, 20 of the power supply unit.

Replacing the battery in the remote control with the proposed power supply unit offers several advantages. Batteries have a limited life. They "sit down", and the remote control stops working at the most inopportune moment, during the evening TV show. For many users (disabled, sick, lonely old people) this becomes a real problem, and in any case, you have to reckon with money spending on

new batteries, and the exhaustion of spent worsens the environment. All this can be avoided by using the proposed power supply unit. It only requires periodic recharging, for which they take the remote control in the hand and shake it in the direction of the tube axis 2, forcing the movable magnet 4 to shuttle relative to the solenoid 3. In 10 seconds of such an operation, an electric power reserve sufficient to switch the remote control 100 times when watching a TV program is generated .

Shown in FIGS. 4, 5, the placement of the power supply in a niche for replaceable batteries of the remote does not require its structural development, so that the proposed unit can be installed in previously manufactured and purchased remote controls. However, in most cases, based on aesthetic, technological and other considerations, it is advisable to initially design a remote control or other device that consumes electricity (a portable radio, player, etc.) to accommodate the proposed power supply unit.

The technical solutions presented above, including the figures, do not exhaust the essence of the utility model. In particular, niches in the housing of the power supply unit for accommodating a rectifier and a charge storage device may have other geometric shapes. The movable magnet and the tube enclosing it may be cylindrical or square in cross section. The end restrictive element for the movable magnet can be placed directly in the tube and is made in the form of an elastic diaphragm, a spring (for example, a leaf) or a fixed (fixed) magnet facing the movable magnet with the same pole. The restrictive element may be directly the end surface of the channel or the housing of the power supply unit. In one block, at the opposite ends of the channel, different restrictive elements can be provided, moreover, at different distances from the solenoid. The electrical terminals of the power supply can be soldered to the corresponding contacts of the consumer device.

By testing prototypes of the proposed power supply unit, it was found that for most applications it is advisable to make a solenoid from copper wire with a diameter of 0.15 mm to 0.5 mm, winding it in an amount of from 2000 to 5000 turns (usually a larger diameter corresponds to a smaller diameter). Recommended relative element sizes for a linear AC pulse generator are within the following limits: external transverse dimension of the solenoid

exceeds the corresponding internal one (1.5-2.5) times, the axial size of the solenoid is (0.75-1.25) the lengths of the movable magnet, the distance from the solenoid to the end of the restrictive element is (0.75-1.5) lengths magnet. For a cylindrical magnet, the recommended length is (0.75 - 1.25) of the diameter.

As follows from the foregoing, the utility model is feasible on the basis of conventional technology. In this case, the movable magnet is made of an alloy having a high magnetic force (for example, “samarium-cobalt”, “neodymium-iron-boron”). The magnet body can be solid or consist of several parts with different characteristics (which is determined, in particular, by the possibilities of manufacturing the magnet).

The scope of the utility model is, first of all, powering low-power consumers - such as hand-held remote controls, signal beacons, portable radios and radio transmitters, players, cell phones, portable electric lights and the like - especially in conditions where there is no possibility of recharging power supply systems of devices from external current sources.

The above confirms the technical result expected from the utility model, consisting in reducing the axial dimension of the power supply unit, which expands the scope of its application.

Claims (21)

1. The power supply unit, comprising a housing, a linear alternating current pulse generator with a fixed solenoid and a movable magnet, installed with the possibility of shuttle movement along the channel passing inside the solenoid, between the end limiting elements located outside the solenoid, electronic means with a current rectifier and a charge storage device, electrical contact terminals for connecting the load, characterized in that the rectifier and the charge storage device are mounted on the periphery of the housing, outside the channel la 2. The power supply unit according to claim 1, characterized in that the current rectifier and the charge storage device are mounted on one side of the solenoid. 3. The power supply unit according to claim 1, characterized in that the current rectifier and the charge storage device are mounted on opposite sides of the solenoid. 4. The power supply unit according to claim 1, characterized in that the charge storage device is an ionistor. 5. The power supply unit according to claim 1, characterized in that the charge storage device is a battery. 6. The power supply unit according to claim 1, characterized in that the charge storage device is a capacitor. 7. The power supply unit according to claim 1, characterized in that the magnet has a cylindrical shape. 8. The power supply unit according to claim 1, characterized in that the magnet has the shape of a rectangular parallelepiped. 9. The power supply unit according to claim 1, characterized in that the end limiting element is an elastic disk. 10. The power supply unit according to claim 1, characterized in that the end restrictive element is an elastic diaphragm. 11. The power supply unit according to claim 1, characterized in that the end limiting element is a spring. 12. The power supply unit according to claim 1, characterized in that the end limiting element is a fixed magnet facing the movable magnet with the same pole. 13. The power supply unit according to claim 1, characterized in that the end restrictive element is the end surface of the channel. 14. The power supply unit according to claim 1, characterized in that the end restrictive element is a body part. 15. The power supply unit according to claim 1, characterized in that the solenoid is made of 2000-5000 turns of copper wire with a diameter of 0.15-0.5 mm. 16. The power supply unit according to claim 1, characterized in that the external transverse size of the solenoid exceeds the corresponding internal one (1.5-2.5) times. 17. The power supply unit according to claim 1, characterized in that the axial size of the solenoid is (0.75-1.25) the lengths of the magnet. 18. The power supply unit according to claim 1, characterized in that the distance from the solenoid to the end restrictive element is (0.75-1.5) magnet lengths. 19. The power supply unit according to claim 7, characterized in that the length of the magnet is (0.75-1.25) of the diameter. 20. The power supply unit according to one of claims 1 to 19, characterized in that it is configured to mount electricity in the consumer device in place of standard power batteries. 21. The power supply unit according to claim 20, characterized in that its housing is equipped with bendable elements for fastening to the consumer device of electricity.