KR101576229B1 - Power supply unit having self power generating function - Google Patents

Abstract

The present invention relates to a self-generating type power supply device and includes a first housing 10 having a coil 45 for generating an induced electromotive force and a permanent magnet 41, a second housing 10 coupled to the first housing 10, A mounting hole 21 in which the rotating body 43 connected to the permanent magnet 41 is mounted, an insertion hole 22 in which one end of the glass bulb 65 is supported, A second housing 20 having a hole 24 formed therein and an operating portion provided in the first housing 10 to rotate the rotating body 43 and a second housing 20 provided in the second housing 20, And fixing means for releasing the fixing of the rotary body 43 so that the rotary body 43 is rotated when the glass bulb 65 ruptures.
According to the present invention, it is possible to quickly and promptly respond to a fire without generating a driving force by using a commercial power source, and it is possible to promptly respond to a power failure so that a fire can be suppressed early.

Description

[0001] Power supply unit having self power generating function [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a self-generating type power supply device, and more particularly, to a self-generating type power supply device that instantaneously generates a voltage using an induced electromotive force generated by rotation of a permanent magnet.

Self-power generation uses a voltage generated by rotating or linearly moving a permanent magnet in a coil, and is used as a head lamp of a bicycle or a constant voltage is generated by a pressure that presses a piezoelectric element. However, such a self-power generation requires a human power or a commercial power source for generating a voltage.

Prior art related to this is "self-generated illumination device of transfer means" disclosed in Korean Utility Model Publication No. 20-0378914 (Mar. 16, 2005).

An object of the present invention is to provide a fire extinguisher which can detect a fire by using a glass bulb and generate an instantaneous voltage by generating an induced electromotive force by using a permanent magnet in a coil when the glass bulb ruptures, And to provide a self-generating power supply that utilizes the self-generated power supply as an expression factor capable of expressing other devices that can be operated by voltage generation.

According to an aspect of the present invention for achieving the above object, the present invention provides a magnetic bearing device including a first housing having permanent magnets for generating an induced electromotive force, a rotating body coupled to the first housing, A second housing provided with an installation hole for receiving one end of the glass bulb and an installation hole for supporting the other end of the glass bulb and an operation part for rotating the rotary body, And fixing means for fixing the rotating body and releasing the rotation of the rotating body so that the rotating body is rotated when the glass bulb ruptures.
Wherein the operating portion is wound on the outer side of the rotating body and the restraining means rotates when the force for fixing the rotating body is removed and the rotating body is rotated to rotate the permanent magnet, And a coil in which an induced electromotive force is generated.

Wherein the actuating portion includes a coil provided on an outer circumferential surface of the rotating body, a base plate disposed on a portion where the first housing and the second housing are coupled with each other to support the coil, And a fixing pin coupled to an end of the rotating body passing through the mounting hole of the second housing.

The restricting means is provided in the mounting hole and is provided in the holding hole formed by communicating the mounting hole and the mounting hole to support the other end of the glass bulb so that the glass bulb receives the designed pressure, And a fixing ball which is in close contact with one surface of the rotating body.

The self-generated power supply device of the present invention is configured such that when the glass bulb ruptures, the rotating body rotates to generate an instantaneous induced electromotive force. In addition, since the glass bulb has a structure that ruptures when heated to a certain temperature, instantaneous induced electromotive force is generated when a fire occurs, and the fire extinguisher can be operated by using it.

Accordingly, it is possible to promptly and promptly respond to a fire without generating a driving force by using a commercial power source, and it is also possible to promptly respond to a power failure so that the fire can be suppressed prematurely.

1 is a cross-sectional view of a preferred embodiment of a self-generating power supply device according to the present invention;
2 is an exploded perspective view of a self-generating power supply device according to the present invention;
3 is a functional diagram of the self-generating power supply device according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the self-generated power supply device of the present invention, when a fire is detected, the glass bulb ruptures and the rotating body rotates. The rotation of the rotating body causes the permanent magnet to be rotated at the designated position, thereby generating an induced electromotive force in the coil and enabling instantaneous voltage generation. The instantaneous voltage is used as an expression factor to express fire extinguishers or other devices that can be activated by instantaneous voltage generation.

When the glass bulb is heated to a certain temperature, the glass bulb is filled with the expanding heat-sensitive liquid. When a fire occurs, the thermal-sensitive liquid filled in the glass bulb expands. When the bulb expands further, the glass bulb ruptures .

1 and 2, a self-generating power supply apparatus provided with a glass bulb will be described.

1 and 2, the self-generating power supply apparatus includes a first housing 10 having a coil 45 and a permanent magnet 41, a second housing 10 coupled to the first housing 10, A mounting hole 21 in which the rotating body 43 connected to the glass bulb 41 is mounted, an insertion hole 22 in which one end of the glass bulb 65 is supported and an installation hole 24 in which the other end of the glass bulb 65 is supported, An operating part provided in the first housing 10 to rotate the rotating body 43 and a second housing 20 provided in the second housing 20 to fix the rotating body 43, And restraining means for releasing the fixing of the rotating body 43 so that the rotating body 43 rotates when the bulb 65 ruptures.
The operating portion is wound around the outer circumference of the rotating body 43. When the restraining means removes the force for fixing the rotating body 43, the rotating body 43 is rotated while the coiled state is released to rotate the permanent magnet 41 And a coil 45 for generating an induced electromotive force when the permanent magnet 41 rotates.

The first housing 10 is installed such that the coil 45 and the permanent magnet 41 are operable and the second housing 20 is mounted with the rotating body 43 connected to the permanent magnet 41.

The first housing 10 is formed in a substantially cylindrical shape and has a coupling portion 11 for coupling with the bracket 30 at its tip end and a space portion 13 having a coil 45 and a permanent magnet 41 , 14 are formed.

The coupling portion 11 corresponds to the coupling hole 31 formed in the bracket 30 and the bolt hole 11a through which the knife block 33 and the anchor bolt 34 are coupled is formed through the center.

The knife block 33 and the anchor bolt 34 are inserted into the bolt hole 11a and the anchor bolt 34 is inserted into the knife block 33. When the anchor bolt 34 is inserted into the knife block 33, It is a fixed structure. The knurl block 33 and the anchor bolt 34 are fastened to the bolt hole 11a so that the force of the engaging portion 11 supported by the engaging hole 31 is increased.

The space portions 13 and 14 mean an inner space formed at a rear end of the first housing 10 and are divided into a first space portion 13 and a second space portion 14 having different inner diameters. The second space 14 has an inner diameter larger than that of the first space 13 and a step 15 is formed between the first space 13 and the second space 14. The step portion 15 is for supporting the bottom plate to be described later.

The second housing 20 has a front end and a rear end different in outer diameter. The outer diameter of the front end of the second housing 20 corresponds to the inner diameter of the second space 14 of the first housing 10, and the outer diameter of the rear end is smaller than that of the front end.

A mounting hole 21 is formed through the center of the second housing 20 and a part of the outer diameter of the second housing 20 protrudes further to form a mounting portion 23. In the present embodiment, the mounting portion 23 is formed such that the outer diameter of the distal end of the second housing 20 is larger than that of the middle portion. An installation hole (24) is formed in the mounting portion (23).

The insertion hole 22 is formed at the tip of the second housing 20 facing the installation hole 24 so that the glass bulb 65 can be installed through the insertion hole 22 and the installation hole 24. That is, the glass bulb 65 is disposed on the outer side of the second housing 20, with one end being supported by the insertion hole 22 and the other end being supported by the installation hole 24.

The operation portion includes a coil 45 provided on the outer circumferential surface of the rotating body 43 and a base plate 47 disposed on a portion where the first and second housings 10 and 20 are coupled to support the coil 45 And a fixing pin 49 coupled to a distal end of the rotating body 43 passing through the mounting hole 21 of the second housing 20 so as to fix the state in which the base plate 47 supports the coil 45 .

The rotating body 43 is for rotating the permanent magnet 41 at a designated position close to the coil 45 by rotating the coil 45 wound on the outer side of the rotating body 43.

The coil 45 rotates the rotating body 43 to rotate the permanent magnet 41. The coil 45 rotates the rotating body 43 while the restraining means is released from the state of being wound on the outer side of the rotating body 43 when the force for fixing the rotating body 43 is removed. The coil 45 employs a helical spring. The position of the coil 45 is fixed by the number of times the coil 45 is wound by the base 47, the second housing 20, and the fixing pin 49 at a constant and fixed position.

An induced electromotive force is generated between the coils 45 when the permanent magnet 41 rotates.

The base plate 47 is formed in the shape of a disk and has a through hole through which the rotating body 43 passes. The bottom plate 47 is disposed between the step portion 15 of the first housing 10 and the second housing 20 to fix the number and position of the winding of the coil 45 and prevent the coil 45 from being projected .

An operating spring 61 is disposed between the permanent magnet 41 and the bottom plate 47 and a contactor 63 is further coupled to the rotating body 43 to which the base plate 47 is coupled. The contactor 63 serves as a rectifying device for converting the induced electromotive force generated in the coil 45 to the direct current by the rotation of the permanent magnet 41. [

The restraining means includes a supporting member provided in the mounting hole 24 and supporting the other end of the glass bulb 65 so that the glass bulb 65 receives the designed pressure and a supporting member provided in the mounting hole 24 to communicate with the mounting hole 21 And a fixing ball 59 provided in the locking hole 57 and brought into close contact with one surface of the rotating body 43 by the glass bulb 65.

The mounting holes 24 are formed in the same direction in the mounting hole 21 and the second housing 20 so that the rotating body 43 and the glass bulb 65 are arranged side by side.

The fixed ball 59 is for restricting the rotation of the rotating body 43. The fixing ball 59 is provided in the engagement hole 57 formed so as to communicate the mounting hole 24 and the mounting hole 21 so that when the glass bulb 65 is mounted to the mounting hole 24, Thereby restricting the rotation of the rotating body 43. As shown in Fig.

The support member is for supporting the other end of the glass bulb 65.

The supporting member includes a support pin 51 coupled to the other end of the glass bulb 65, a fixing screw 53 coupled to an end of the mounting hole 24, And a support pin spring 55 arranged to elastically support the other end of the glass bulb 65 in the direction of the insertion hole 22.

One end of the glass bulb 65 is supported by the insertion hole 22 and the other end is supported by the support pin 51, the fixing screw 53 and the support pin spring 55 so as to be subjected to the designed pressure.

On the other hand, a bracket 30 is provided for fixing the self-generating-type power supply device to a ceiling or a wall surface.

The bracket 30 has a substantially "A" shape and is formed at one side thereof with a coupling hole 31 into which the coupling portion 11 of the first housing 10 is inserted and with a coupling hole 32 at the other side thereof . The shape of the bracket can adopt various shapes besides the letter "a".

The engaging hole 31 formed in the bracket 30 and the engaging portion 11 of the first housing 10 are elliptical in order to prevent relative rotation.

A shielding stopper 35 for integrating the first housing 10 and the bracket 30 is provided. The shielding stopper 35 is press-fitted into the engaging portion 11 inserted into the engaging hole 31 to fix the first housing 10 to the bracket 30.

The self-generated power supply device described above has a rectifier for converting a voltage generated by the induction electromotive force into a direct current. When the permanent magnet 41 is rotated, an induced electromotive force is generated in the coil. Since the induced electromotive force is an alternating current, a rectifying device is provided to make the direct current. As for the rectifying device, the contactor 63 plays the role as described above.

The induced electromotive force, ie, the voltage generated by DC through the rectifier, is used as an expression factor that can be used to extinguish a fire or other devices that can be operated by instantaneous voltage generation.

And an amplifying device for amplifying the voltage generated by the induced electromotive force. Voltage amplification is intended to make the induced electromotive force a minimum voltage for use as an expression factor in a fire extinguisher or other device. The amplification of the induced electromotive force can be controlled by the number of times the coil 45 is wound. In addition, the above-described operation spring can perform the amplification of the induced electromotive force.

Hereinafter, the operation of the present invention will be described.

1 and 2, a process of assembling the self-generating power supply apparatus of the present invention and installing it on a ceiling or a wall will be described first.

The rotating body 43 to which the permanent magnets 41 are connected is inserted into the space portions 13 and 14 of the first housing 10 and the operating springs 61, 63, and a coil (helical spring) 45 in this order. Next, the second housing 20 is coupled to the first housing 10 so that the rotating body 43 passes through the mounting hole 21 of the first housing 10.

The end of the rotating body 43 is projected to the outside through the mounting hole 21 of the second housing 20 and the fixing pin 49 is engaged with the projecting end, The installation of the permanent magnet 41 and the rotating body 43 is completed in the housing 20. At this time, a screw thread is formed at the end of the rotating body 43, and the fixing pin 49 is also nut-shaped, so that the coupling is easy.

The number and position of the coil 45 wound between the bottom plate 47 and the second housing 20 are fixed by the engagement of the fixing pin 49.

Next, a glass bulb (65) is provided in the mounting hole (24) of the second housing (20).

In the installation of the glass bulb 65, the fixing ball 59 is inserted into the fixing hole 57 for communicating the mounting hole 24 with the mounting hole 21 and the glass bulb 65 is installed in the mounting hole 24 .

The glass bulb 65 is installed such that one end thereof is inserted into the insertion hole 22 of the second housing 20 and the other end thereof is located in the installation hole 24. To this end, the tip of the glass bulb 65 having the support pin 51 at the other end is inserted into the insertion hole 22 through the installation hole 24, and the support pin spring 55 and the fixing screw 53 are sequentially You can combine them.

Then the glass bulb 65 is subjected to the pressure designed by the support pin spring 55 and the fixing ball 59 is brought into close contact with one surface of the rotating body 43 by the glass bulb 65, .

In this state, the bracket 30 is engaged with the first housing 10. The engaging portion 11 of the first housing 10 is inserted into the engaging hole 31 of the bracket 30 and the bolt hole 11a formed in the engaging portion 11 is provided with a knock block 33, (34) are sequentially inserted, and then the shielding stopper (35) is engaged with the engaging portion (11).

Then, the self-generated power supply device is assembled, and the assembled self-generated power supply device places the bracket 30 on the ceiling or the wall surface and fixes the bolt to the ceiling or the wall surface by fastening the bolt to the fastening hole 32 .

At this time, the self-generating type power supply installed on the ceiling or the wall can be used as a fire extinguisher for extinguishing the fire or as an expression factor for expressing other devices that can be operated by the momentary voltage generation, Or other device.

If a fire occurs in this state, the heat sensitive liquid of the glass bulb 65 is expanded due to the temperature change in the installed space and ruptures when it expands further. At this time, since the glass bulb 65 is under the pressure designed by the support pin spring 55, it is detached from the installation hole 24 when it ruptures.

When the glass bulb 65 is disengaged from the mounting hole 24, the fixing ball 59, which is in close contact with the rotating body 43, is pushed in the direction of the mounting hole 24 from the engaging hole 57, The restraint of the rotating body 43 by the glass bulb 65 is released.

When the permanent magnet 41 is rotated by the rotation of the rotating body 43, an induced electromotive force is generated.

The induced electromotive force generated by the rotation of the permanent magnet 41 instantaneously generates a voltage and the generated voltage is amplified by the coil 45 and the operating spring 61 and converted into direct current by the contactor 63, The power supply to the fire extinguisher or other device that extinguishes the fire extinguisher.

A fire extinguisher or other device can then be activated and quickly extinguish the fire.

Since the self-generated power supply device generates the induction electromotive force in the coil while the permanent magnet rotates, the rotational speed and the rotational amount of the permanent magnet are uniform, and thus the electromotive force generation amount is uniform and it is advantageous to instantaneously generate the voltage.

This is because if the amount of generated electromotive force is not uniform, a problem may arise in generating an instantaneous voltage and an operation reliability problem arises.

As described above, the self-generating type power supply apparatus provided with the glass bulb 65 and the rotating body 43 can operate the fire extinguisher in case of fire without generating a driving force by using a commercial power source, Rapid response is possible.

It is to be understood that the invention is not limited to the disclosed embodiments, but is capable of many modifications and alterations, all of which are within the scope of the appended claims. It is self-evident.

10: first housing 11:
13, 14: first and second space portions 15:
20: second housing 21: mounting hole
22: insertion hole 23: installation part
24: Mounting hole 30: Bracket
31: engaging hole 32: engaging hole
33: Sword block 34: Anchor bolt
35: shielding plug 41: permanent magnet
43: Rotor 45: Coil
47: Base plate 49: Fixing pin
51: Support pin 53: Fixing screw
55: support pin spring 57: latching hole
59: stationary ball 61: operating spring
63: contactor 65: glass bulb

Claims (8)

A first housing having permanent magnets;
A second housing coupled to the first housing and having a mounting hole for mounting a rotating body connected to the permanent magnet, an insertion hole for supporting one end of the glass bulb, and a mounting hole for supporting the other end of the glass bulb;
An operating part provided in the first housing for rotating the rotating body to rotate the permanent magnet;
And restricting means provided in the second housing for fixing the rotating body and releasing the rotation of the rotating body so that the rotating body is rotated when the glass bulb ruptures,
The operating portion
Wherein when the force for fixing the rotating body is removed, the rotating body is rotated to rotate the permanent magnet, and when the permanent magnet is rotated, the induced electromotive force A generating coil,
A base plate disposed at a portion where the first housing and the second housing are coupled to support the coil,
And a fixing pin coupled to an end of the rotating body through the mounting hole of the second housing to fix the state that the base supports the coil,
Wherein the coil is a helical spring wound a plurality of times,
Further comprising an amplifying device for amplifying a voltage generated by the induced electromotive force. The method according to claim 1,
The restraining means
A support member provided in the installation hole and supporting the other end of the glass bulb so that the glass bulb receives the designed pressure,
And a fixing ball provided in a locking hole formed by communicating the mounting hole and the mounting hole and being in close contact with a surface of the rotating body by the glass bulb. The method of claim 2,
The support member
A support pin coupled to the other end of the glass bulb,
A fixing screw coupled to an end of the mounting hole,
And a support pin spring disposed between the support pin and the fixing screw and elastically supporting the other end of the glass bulb in the direction of the insertion hole. delete delete delete delete The method according to claim 1,
Wherein the glass bulb is filled with a thermally sensitive liquid which expands when heated to a predetermined temperature.

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