CN113390070A - Driving power supply of LED lamp with overheat protection function - Google Patents

Abstract

The invention discloses a driving power supply of an LED lamp with an overheat protection function, which specifically comprises the following components: the power supply comprises a power supply shell, a power supply body and a heat absorption device, wherein the power supply body is arranged in the power supply shell, and the two sides of the power supply body are provided with the heat absorption devices; the control device is arranged inside the power supply shell, and two ends of the control device are communicated with the adsorption device through a guide pipe; the heat sink includes: the LED lamp driving device comprises a heat absorption shell, wherein a heat dissipation cylinder is arranged inside the heat absorption shell, a heat absorption sheet is fixedly connected to the outer side of the heat dissipation cylinder, one end, far away from the heat dissipation cylinder, of the heat absorption sheet extends onto a power supply body and is fixedly connected with the power supply body, and one end of the heat dissipation cylinder is communicated with a control device through a guide pipe. This drive power supply of LED lamp with overheat protection function, convenient protection power supply avoids the power overheat to damage, can open according to the temperature is automatic to stop, need not manual operation, convenient to use.

Description

Driving power supply of LED lamp with overheat protection function

Technical Field

The invention relates to the technical field of LED lamp driving power supplies, in particular to a driving power supply of an LED lamp with an overheat protection function.

Background

An LED driving power supply is a power converter that converts a power supply into a specific voltage and current to drive an LED to emit light, and generally: the input of the LED driving power source includes high-voltage power frequency alternating current (i.e. commercial power), low-voltage direct current, high-voltage direct current, low-voltage high-frequency alternating current (e.g. output of an electronic transformer), etc., while the output of the LED driving power source is mostly a constant current source which can change voltage along with the change of the forward voltage drop value of the LED, and as the application of the LED is increasingly widespread, the performance of the LED driving power source will be more and more suitable for the requirements of the LED. The drive power supply of present LED lamp produces higher temperature often easily in the use, when needs use in the higher environment of temperature, the power is burnt out easily after the temperature of environment and the high temperature that power work produced reach the certain degree.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a driving power supply of an LED lamp with an overheat protection function, which solves the problems that the conventional driving power supply of the LED lamp is easy to generate higher temperature in the use process, and when the conventional driving power supply is required to be used in an environment with higher temperature, the environment temperature and the high temperature generated by the power supply work reach a certain degree, and then the power supply is easy to burn out.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: a driving power supply of an LED lamp with an overheat protection function specifically comprises:

the power supply comprises a power supply shell, a power supply body and a heat absorption device, wherein the power supply body is arranged in the power supply shell, and the two sides of the power supply body are provided with the heat absorption devices;

the control device is arranged inside the power supply shell, and two ends of the control device are communicated with the adsorption device through a guide pipe;

the heat sink includes:

the heat absorption device comprises a heat absorption shell, a heat dissipation cylinder and a control device, wherein a heat absorption sheet is fixedly connected to the outer side of the heat dissipation cylinder, one end, far away from the heat dissipation cylinder, of the heat absorption sheet extends onto the power supply body and is fixedly connected with the power supply body, and one end of the heat dissipation cylinder is communicated with the control device through a guide pipe;

the control device includes:

the bottom of the switch device is fixedly connected with the bottom of the inner wall of the power supply shell through a fixing seat, two ends of the switch device are communicated with limiting devices, and one ends, far away from the switch device, of the limiting devices are communicated with the heat dissipation cylinder through guide pipes.

After the inside power body of power shell produced the heat, the heat passes through the heat absorbing sheet and transmits inside the heat sink, the inside radiator tube of heat sink spreads the heat to the inside thermal expansion medium of heat sink shell, the inside stop device of expansion promotion controlling means after the thermal expansion medium is heated, trigger switch device closes, can cut off the power body and be connected with outside consumer, thereby close the power body, conveniently protect the power, avoid the power overheated damage, be provided with the heat sink, be provided with the heat absorbing sheet when the inside heat absorbing sheet that is provided with of heat sink, be connected the inside thermal expansion medium of heat sink with the power body through the heat absorbing sheet, can transmit the heat on the power body to the thermal expansion medium inside fast, and the thermal expansion medium be heated and not influenced by the inside air distribution of power shell, the response is more quick accurate.

Preferably, the heat absorption shell is filled with a liquid thermal expansion medium, and the heat absorption sheets are provided with a plurality of groups and are uniformly distributed on the outer side of the heat dissipation cylinder.

Preferably, the switch device comprises a switch sleeve, the inner wall of the switch sleeve is respectively connected with a sub switch and a mother switch in a sliding mode, one side, back to the back, of the sub switch and one side, back to the back, of the mother switch are respectively connected with a top plate through a jacking spring, and the top plate is far away from the jacking spring and is connected with a first piston through a connecting plate.

The switch device is provided with a sub switch and a main switch, when a thermal expansion medium in the heat absorption device begins to expand, a first piston is pushed to move, the first pistons at two ends of a switch sleeve respectively push the sub switch and the main switch to move through a top plate, so that the sub switch and the main switch are separated, the sub switch and the main switch are bridge beams connected between a power supply body and external electric equipment, after the sub switch is separated from the main switch, the power supply body is disconnected with the external electric equipment, the arranged sub switch and the main switch can be opened and closed for multiple times, the repeated use is convenient, after the temperature is reduced, the first piston can be reset to automatically drive the sub switch and the main switch to be attached again, the manual operation is not needed, the use is convenient, the top plate and a jacking spring are arranged, when the first piston is reset, the sub switch and the main switch are attached, and the sub switch and the main switch are pressed together through the elasticity of the jacking spring, poor contact between the sub-switch and the main switch can be avoided, and the use is safer and more reliable.

Preferably, both ends of the switch sleeve are communicated with the limiting device, and one end, far away from the connecting plate, of the first piston extends into the limiting device.

Preferably, stop device includes limiting sleeve, limiting chute and slide opening have been seted up respectively to limiting sleeve inner wall, limiting chute inner wall sliding connection has the stopper, the draw-in groove has been seted up at the stopper top, slide opening inner wall sliding connection has the second piston, second piston one end extends to limiting sleeve outside and fixedly connected with arc connection piece through the slide opening, the one end fixedly connected with card of second piston is kept away from to the arc connection piece.

The limiting device is arranged, when the first piston is pushed by the thermal expansion medium to move, because the thermal expansion medium is heated and then the expansion pressure is larger, the displacement of the first piston can be controlled by a limit chute in the limit device, so that the first piston is prevented from extruding other components, the first piston and the switch device can be protected, and is provided with a slide hole and a second piston, when the pressure in the limiting sleeve is increased, the second piston is pushed to move upwards, the second piston drives the clamping piece to move upwards through the arc-shaped connecting sheet, when the pressure in the limiting sleeve reaches a certain degree, the card withdraws from the clamping groove, the limiting block and the first piston can move, the switch device can be triggered after the temperature in the power supply shell reaches a certain degree, and the first piston can move rapidly under a larger pressure, so that the condition that the contact failure between the sub switch and the main switch is caused due to slow movement is avoided.

Preferably, one end of the limiting sleeve, which is close to the limiting sliding groove, is communicated with the switch sleeve, and one end of the limiting sleeve, which is close to the sliding hole, is communicated with the guide pipe.

Preferably, one side of the limiting block, which is far away from the clamping groove, is fixedly connected with the side surface of the first piston, and the bottom of the card penetrates through the limiting sleeve and extends into the clamping groove.

(III) advantageous effects

The invention provides a driving power supply of an LED lamp with an overheat protection function. The method has the following beneficial effects:

(1) this kind of drive power supply of LED lamp with overheat protection function, after the inside power body of power shell produced the heat, the heat transmits to the heat-sink through the heat absorbing sheet inside, the inside radiating cylinder of heat-sink spreads the heat to the inside thermal expansion medium of heat-sink shell, the inside stop device of expansion promotion controlling means after the thermal expansion medium is heated, trigger switch device closes, can cut off being connected of power body and outside consumer, thereby close the power body, conveniently protect the power, avoid power overheat damage.

(2) This kind of drive power supply of LED lamp with overheat protection function is provided with the heat sink, and when the inside heat absorption piece that is provided with of heat sink, through this body coupling of heat absorption piece with the inside thermal expansion medium of heat sink, can transmit the heat on the power supply body to the thermal expansion medium inside fast to being heated of thermal expansion medium is not influenced by the inside air distribution of power supply housing, and the response is quick accurate more.

(3) This kind of drive power supply of LED lamp with overheat protection function, be provided with switching device, inside sub-switch and the female switch of being provided with of switching device, when the inside thermal expansion medium of heat sink begins to expand, promote first piston and remove, the first piston at switch sleeve both ends promotes sub-switch and female switch through the roof respectively and removes, thereby with sub-switch and female switch separation, power supply body promptly with outside consumer disconnection, can open and shut many times between the sub-switch that sets up and the female switch, make things convenient for repetitious usage, after the temperature reduces, first piston resets and can automatically take sub-switch and female switch to laminate once more, need not manual operation, high durability and convenient use.

(4) This kind of drive power supply of LED lamp with overheat protection function is provided with roof and the tight spring in top, and when first piston reset, sub-switch and female switch laminating to elasticity through the tight spring in top compresses tightly sub-switch and female switch together, can avoid contact failure between sub-switch and the female switch, uses safe and reliable more.

(5) This kind of drive power supply of LED lamp with overheat protection function is provided with stop device, receives the thermal expansion medium to promote and when removing when first piston, because the thermal expansion medium is heated after expansion pressure great, the displacement volume of the inside spacing spout control first piston of accessible stop device avoids first piston extrusion other components and parts, can protect first piston and switching device.

(6) This kind of drive power supply of LED lamp with overheat protection function, be provided with slide opening and second piston, when the inside pressure increase of limit sleeve, promote the second piston rebound, the second piston passes through the arc connection piece and drives the card rebound, when the inside pressure of limit sleeve reaches the certain degree, the card withdraws from the draw-in groove is inside, stopper and first piston can remove, just trigger switch device after can making the inside temperature of power supply housing reach the certain degree, and can make first piston quick travel under great pressure, avoid slow movement to lead to sub-switch and mother switch to produce the bad condition emergence of contact.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of a control device according to the present invention;

FIG. 3 is a schematic view of a heat sink according to the present invention;

FIG. 4 is a schematic view of the switching device of the present invention;

fig. 5 is a schematic structural view of the limiting device of the present invention.

In the figure: 1. power supply shell, 2, power supply body, 3, heat sink, 31, heat sink shell, 32, heat dissipation cylinder, 33, heat absorbing sheet, 4, controlling means, 41, switching device, 411, switch sleeve, 412, sub-switch, 413, female switch, 414, roof, 416, top spring, 417, connecting plate, 418, first piston, 42, stop device, 421, spacing sleeve, 422, spacing spout, 423, slide opening, 424, stopper, 425, draw-in groove, 426, second piston, 427, arc connection piece, 428, card, 5, pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

referring to fig. 1-3, the present invention provides a technical solution: a driving power supply of an LED lamp with an overheat protection function specifically comprises:

the power supply comprises a power supply shell 1, wherein a power supply body 2 is arranged inside the power supply shell 1, and heat absorption devices 3 are arranged on two sides of the power supply body 2;

the control device 4 is arranged inside the power supply shell 1, and two ends of the control device 4 are communicated with the adsorption device 3 through the guide pipe 5;

the heat sink 3 includes:

the heat absorption shell 31 is internally provided with a heat dissipation cylinder 32, the outer side of the heat dissipation cylinder 32 is fixedly connected with a heat absorption sheet 33, one end of the heat absorption sheet 33, which is far away from the heat dissipation cylinder 32, extends onto the power supply body 2 and is fixedly connected with the power supply body 2, and one end of the heat dissipation cylinder 32 is communicated with the control device 4 through a conduit 5;

the control device 4 includes:

the bottom of the switch device 41 is fixedly connected with the bottom of the inner wall of the power supply shell 1 through a fixed seat, two ends of the switch device 41 are both communicated with limit devices 42, and one end, away from the switch device 41, of each limit device 42 is communicated with the heat dissipation cylinder 32 through a guide pipe 5.

When the power body 2 in the power housing 1 generates heat, the heat is transferred to the inside of the heat absorbing device 3 through the heat absorbing sheet 33, the heat dissipating cylinder 32 in the heat absorbing device 3 disperses the heat into the thermal expansion medium in the heat absorbing housing, the thermal expansion medium expands to push the limiting device 42 in the control device 4 after being heated, the trigger switch device 41 is turned off, so as to cut off the connection between the power body 2 and the external electric equipment, thereby turning off the power body 2, protecting the power conveniently, avoiding the power from being damaged due to overheating, the heat absorbing device 3 is provided, when the heat absorbing device 3 is internally provided with the heat absorbing sheet 33, the thermal expansion medium in the heat absorbing device 3 is connected with the power body 2 through the heat absorbing sheet 33, the heat on the power body 2 can be rapidly transferred to the inside of the thermal expansion medium, and the thermal expansion medium is not affected by the air distribution in the power housing 1, the response is faster and more accurate.

Example two:

referring to fig. 1-4, the present invention provides a technical solution based on the first embodiment: switch device 41 includes switch sleeve 411, and switch sleeve 411 inner wall sliding connection has sub-switch 412 and female switch 413 respectively, and one side that sub-switch 412 and female switch 413 carried on the back all is connected with roof 414 through top tension spring 416 fixedly connected, and roof 414 keeps away from top tension spring 416 is connected with first piston 418 through connecting plate 417, and switch sleeve 411 both ends all communicate with stop device 42, and the one end that connecting plate 417 was kept away from to first piston 418 extends to inside stop device 42.

The switch device 41 is provided, the sub switch 412 and the mother switch 413 are arranged in the switch device 41, when the thermal expansion medium in the heat absorbing device 3 begins to expand, the first piston 418 is pushed to move, the first pistons 418 at two ends of the switch sleeve 411 respectively push the sub switch 412 and the mother switch 413 to move through the top plate 414, so that the sub switch 412 and the mother switch 413 are separated, because the sub switch 412 and the mother switch 413 are bridge beams connected between the power body 2 and external electric equipment, after the sub switch 412 is separated from the mother switch 413, the power body 2 is disconnected with the external electric equipment, the arranged sub switch 412 and the mother switch 413 can be opened and closed for multiple times, the multiple use is convenient, after the temperature is reduced, the first piston 418 is reset, the sub switch 412 and the mother switch 413 can be automatically attached again, the manual operation is not needed, the use is convenient, the top plate 414 and the tightening spring 416 are arranged, when the first piston 418 is reset, the sub switch 412 is attached to the main switch 413, and the sub switch 412 and the main switch 413 are pressed together by the elastic force of the jacking spring 416, so that poor contact between the sub switch 412 and the main switch 413 can be avoided, and the use is safer and more reliable.

Example three:

referring to fig. 1-5, the present invention provides a technical solution based on the first embodiment and the second embodiment: stop device 42 includes limiting sleeve 421, limiting chute 422 and sliding hole 423 have been seted up respectively to limiting sleeve 421 inner wall, limiting chute 422 inner wall sliding connection has stopper 424, draw-in groove 425 has been seted up at the stopper 424 top, sliding hole 423 inner wall sliding connection has second piston 426, second piston 426 one end is extended to limiting sleeve 421 outside and fixedly connected with arc connection piece 427 through sliding hole 423, the one end fixedly connected with card 428 of second piston 426 is kept away from to arc connection piece 427, limiting sleeve 421 is close to limiting chute 422's one end and switch sleeve 411 intercommunication, limiting sleeve 421 is close to the one end and the pipe 5 intercommunication of sliding hole 423, one side and the first piston 418 side fixed connection of draw-in groove 425 are kept away from to stopper 424, card 428 bottom runs through limiting sleeve 421 and extends to inside draw-in groove 425.

The limiting device 42 is arranged, when the first piston 418 is pushed by a thermal expansion medium to move, because the expansion pressure of the thermal expansion medium is larger after the thermal expansion medium is heated, the displacement of the first piston 418 can be controlled through the limiting chute 422 in the limiting device 42, the first piston 418 is prevented from extruding other components, the first piston 418 and the switch device 41 can be protected, the sliding hole 423 and the second piston 426 are arranged, when the pressure in the limiting sleeve 421 is increased, the second piston 426 is pushed to move upwards, the second piston 426 drives the card 428 to move upwards through the arc connecting sheet 427, when the pressure in the limiting sleeve 421 reaches a certain degree, the card 428 is withdrawn from the clamping groove 425, the limiting block 424 and the first piston 418 can move, the switch device 41 can be triggered after the temperature in the power supply shell 1 reaches a certain degree, and the first piston 418 can move rapidly under a larger pressure, the condition that the sub switch 412 and the mother switch 413 are in poor contact due to slow movement is avoided.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. The term "comprising", without further limitation, means that the element so defined is not excluded from the group consisting of additional identical elements in the process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A driving power supply of an LED lamp with an overheat protection function specifically comprises:

the power supply comprises a power supply shell (1), wherein a power supply body (2) is arranged in the power supply shell (1), and heat absorption devices (3) are arranged on two sides of the power supply body (2);

the control device (4), the control device (4) is arranged inside the power supply shell (1), and both ends of the control device (4) are communicated with the adsorption device (3) through a conduit (5);

the driving power supply of the LED lamp with the overheat protection function is characterized in that: the heat sink (3) comprises:

the heat absorption device comprises a heat absorption shell (31), wherein a heat dissipation cylinder (32) is arranged inside the heat absorption shell (31), a heat absorption sheet (33) is fixedly connected to the outer side of the heat dissipation cylinder (32), one end, far away from the heat dissipation cylinder (32), of the heat absorption sheet (33) extends onto the power supply body (2) and is fixedly connected with the power supply body (2), and one end of the heat dissipation cylinder (32) is communicated with a control device (4) through a guide pipe (5);

the control device (4) comprises:

the bottom of the switch device (41) is fixedly connected with the bottom of the inner wall of the power supply shell (1) through a fixed seat, two ends of the switch device (41) are communicated with limit devices (42), and one end, far away from the switch device (41), of each limit device (42) is communicated with the heat dissipation cylinder (32) through a guide pipe (5).

2. The driving power supply of the LED lamp with the overheat protection function according to claim 1, wherein: the heat absorption shell is filled with liquid thermal expansion media, and the heat absorption sheets (33) are arranged in multiple groups and are uniformly distributed on the outer side of the heat dissipation cylinder (32).

3. The driving power supply of the LED lamp with the overheat protection function according to claim 1, wherein: the switch device (41) comprises a switch sleeve (411), the inner wall of the switch sleeve (411) is respectively connected with a sub switch (412) and a mother switch (413) in a sliding mode, one side, back to the back, of each of the sub switch (412) and the mother switch (413) is fixedly connected with a top plate (414) through a jacking spring (416), and the top plate (414) is far away from the jacking spring (416) and is connected with a first piston (418) through a connecting plate (417).

4. The driving power supply of the LED lamp with the overheat protection function according to claim 3, wherein: both ends of the switch sleeve (411) are communicated with the limiting device (42), and one end, far away from the connecting plate (417), of the first piston (418) extends into the limiting device (42).

5. The driving power supply of the LED lamp with the overheat protection function according to claim 1, wherein: stop device (42) include stop sleeve (421), stop chute (422) and slide opening (423) have been seted up respectively to stop sleeve (421) inner wall, stop chute (422) inner wall sliding connection has stopper (424), draw-in groove (425) have been seted up at stopper (424) top, slide opening (423) inner wall sliding connection has second piston (426), second piston (426) one end extends to outside and fixedly connected with arc connection piece (427) of stop sleeve (421) through slide opening (423), one end fixedly connected with card (428) of second piston (426) are kept away from to arc connection piece (427).

6. The driving power supply of the LED lamp with the overheat protection function according to claim 5, wherein: one end, close to the limiting sliding groove (422), of the limiting sleeve (421) is communicated with the switch sleeve (411), and one end, close to the sliding hole (423), of the limiting sleeve (421) is communicated with the guide pipe (5).

7. The driving power supply of the LED lamp with the overheat protection function according to claim 5, wherein: one side of the limiting block (424), which is far away from the clamping groove (425), is fixedly connected with the side face of the first piston (418), and the bottom of the clamping piece (428) penetrates through the limiting sleeve (421) and extends into the clamping groove (425).

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