CN113203070A

CN113203070A - LED infrared induction lamp with emergency function

Info

Publication number: CN113203070A
Application number: CN202110535264.7A
Authority: CN
Inventors: 王明威
Original assignee: Jilin Agricultural Science and Technology College
Current assignee: Foshan City Love Home Photoelectric Co ltd
Priority date: 2021-05-17
Filing date: 2021-05-17
Publication date: 2021-08-03
Anticipated expiration: 2041-05-17
Also published as: CN113203070B

Abstract

The invention discloses an LED infrared induction lamp with an emergency function, which comprises a shell, wherein an air outlet cover is sleeved on the top of the shell in a threaded manner, connecting rods are fixedly connected to two sides of the bottom of the air outlet cover, one end, far away from the air outlet cover, of each connecting rod is fixedly connected with a fan, supporting plates are fixedly connected to the bottoms of two sides of the shell, a circuit board is placed on the top of each supporting plate, an LED luminous body is fixedly connected to the bottom of each circuit board, a storage battery is arranged on the top of each circuit board, and clamping holes are formed in the bottoms of two sides of the shell. The LED infrared induction lamp has the advantages of being capable of being used through emergency power supply of the storage battery, automatically dissipating heat and being long in service life, and solves the problems that an existing LED infrared induction lamp does not have an emergency function, cannot be used and automatically dissipated heat under the condition of power failure, is low in heat dissipation efficiency during working, seriously influences the service life of the LED infrared induction lamp and increases use cost.

Description

LED infrared induction lamp with emergency function

Technical Field

The invention relates to the technical field of LED infrared induction lamps, in particular to an LED infrared induction lamp with an emergency function.

Background

The LED infrared induction lamp is a new generation intelligent illuminating lamp which detects the state of the light environment by sensing the infrared heat radiation of a human body and turns on and off the lamp through a built-in delay switch, and is also called as an LED human body induction lamp.

The existing LED infrared induction lamp does not have an emergency function, cannot be used under the condition of power failure, cannot automatically dissipate heat, is low in heat dissipation efficiency during working, seriously influences the service life of the LED infrared induction lamp, and increases the use cost.

Disclosure of Invention

The invention aims to provide an LED infrared induction lamp with an emergency function, which has the advantages of automatic heat dissipation and long service life by using a storage battery for emergency power supply, and solves the problems that the existing LED infrared induction lamp does not have the emergency function, cannot be used under the condition of power failure, cannot automatically dissipate heat, has low heat dissipation efficiency during working, seriously influences the service life of the lamp per se and increases the use cost.

In order to achieve the purpose, the invention provides the following technical scheme: an LED infrared induction lamp with an emergency function comprises a shell, wherein a vent cover is sleeved on the top of the shell in a threaded manner, connecting rods are fixedly connected to two sides of the bottom of the vent cover, one end, away from the vent cover, of each connecting rod is fixedly connected with a fan, a supporting plate is fixedly connected to the bottom of two sides of the shell, a circuit board is placed on the top of the supporting plate, an LED luminous body is fixedly connected to the bottom of the circuit board, a storage battery is arranged on the top of the circuit board, clamping holes are formed in the bottoms of two sides of the shell, fixing tubes are fixedly connected to two sides of the top of the circuit board, springs are fixedly connected to the inner walls of the fixing tubes, clamping rods are fixedly connected to one sides, away from the inner walls of the fixing tubes, of the springs, one ends, away from the springs, of the clamping rods extend to inner cavities of the clamping holes, long holes are formed in the tops of the fixing tubes, and vertical rods are fixedly connected to the tops of the clamping rods, the top of montant runs through the slot hole and extends to the inner chamber of casing, the top of circuit board just is located the front side fixedly connected with temperature sensor and controller respectively of battery, the bottom fixedly connected with lamp shade of casing.

Preferably, both sides of the bottom of the circuit board are fixedly connected with positioning rods, the top of the supporting plate is provided with positioning holes, and the bottoms of the positioning rods extend to inner cavities of the positioning holes.

Preferably, a heat conducting plate penetrates through the surface of the shell, and one side of the heat conducting plate penetrates through the shell and extends to the inner cavity of the shell.

Preferably, the both sides of battery all are provided with the flexure strip, and the one side fixedly connected with locating plate of battery is kept away from to the flexure strip, the bottom and the circuit board fixed connection of locating plate.

Preferably, the output end of the temperature sensor is electrically connected with the controller, and the controller is electrically connected with the fan and the LED luminous body.

Preferably, the controller is electrically connected with the upper computer through a communication circuit; the upper computer be used for the stability and the temperature control parameter through the electric wire netting come the timely early warning information of feedback and send early warning control signal in order to instruct the controller to make early warning action instruction to the controller, early warning action instruction include controller control LED luminous element stroboscopic in order reminding the user to close the power to if still detect LED luminous element and have operating current then controller control LED luminous element is closed by oneself after reminding many times.

Preferably, the upper computer comprises a management unit, a power grid stability evaluation unit, a temperature control parameter learning unit, a temperature control early warning unit and a power grid early warning unit which are connected,

the power grid stability evaluation unit is used for obtaining historical data of a power grid and environmental data such as thunder and lightning and the like to evaluate the stability of the power grid in at least one period in the future;

the temperature control parameter learning unit is used for acquiring historical data of temperature control parameters and current temperature control parameter data to evaluate the heat generation energy efficiency of the LED luminous body in at least one period in the future;

the temperature control early warning unit is used for acquiring heat production energy efficiency of at least one period in the future for evaluation and sending early warning data to the management unit when the heat production energy efficiency result exceeds a threshold value so as to trigger the management unit to send an early warning control signal to the controller to guide the controller to make an early warning action instruction;

the power grid early warning unit is used for obtaining the stability of at least one period of the power grid in the future for evaluation and sending early warning data to the management unit when the evaluation result exceeds a threshold value so as to trigger the management unit to send an early warning control signal to the controller to guide the controller to make an early warning action instruction.

Preferably, the obtaining of the historical data of the temperature control parameter and the current temperature control parameter data to evaluate the heat generation energy efficiency of the LED luminary in at least one future cycle specifically: the method comprises the steps of firstly obtaining historical data of temperature control parameters, wherein the historical data of the temperature control parameters comprise historical collected data of a temperature sensor and control data of a simultaneous controller, establishing a historical temperature change reference function through the historical collected data of the temperature sensor, then singly establishing a control intervention function based on the control data of the simultaneous controller, convolving the control intervention function and the temperature change reference function to obtain a comprehensive equivalent temperature control function, reconfiguring the comprehensive equivalent temperature control function in the historical data updating of the temperature control parameters, and then inputting current temperature control parameter data by using the comprehensive equivalent temperature control function to evaluate the heat production energy efficiency of at least one future period of the LED luminous body, wherein the evaluation result is an output numerical value of the comprehensive equivalent temperature control function.

Compared with the prior art, the invention has the beneficial effects that:

the LED infrared induction lamp has the advantages of being capable of supplying power through the storage battery in an emergency, automatically dissipating heat and being long in service life by matching the shell, the air outlet cover, the connecting rod, the fan, the supporting plate, the circuit board, the LED luminous body, the storage battery, the clamping hole, the fixing pipe, the spring, the clamping rod, the long hole, the vertical rod, the temperature sensor and the controller, and solves the problems that an existing LED infrared induction lamp does not have an emergency function, cannot be used and automatically dissipated heat under the condition of power failure, is low in heat dissipation efficiency during working, seriously influences the service life of the LED infrared induction lamp and increases use cost.

The positioning rod, the supporting plate and the positioning hole are arranged, so that the circuit board can be positioned and supported, the circuit board is convenient to install, the heat conducting plate can absorb heat in the inner cavity of the shell and conduct the heat to the outside, the heat is convenient to dissipate, the elastic piece can be in close contact with the conductive end of the storage battery, the storage battery is convenient to stably install, the spring is arranged to generate tension on the clamping rod, the clamping rod is enabled to extend into the inner cavity of the clamping hole, the circuit board is fixedly installed, the vertical rod is arranged to facilitate driving the clamping rod to transversely move away from the clamping hole, the circuit board is convenient to disassemble, and the air outlet cover is arranged to facilitate circulation of air between the inner cavity of the shell and the outside.

Particularly, the invention can feed back timely early warning information through the upper computer based on the stability of the power grid and temperature control parameters and send early warning control signals to the controller to guide the controller to make early warning action instructions, so that the LED luminous body can be prevented from being damaged in emergency situations. Moreover, the invention provides a scientific method for evaluating the heat production energy efficiency of the LED luminous body in at least one future period by acquiring the historical data of the temperature control parameters and the current temperature control parameter data, and the heat production energy efficiency of the LED luminous body in at least one future period can be effectively evaluated.

Drawings

FIG. 1 is a schematic cross-sectional view of the structure of the present invention;

FIG. 2 is an enlarged view of a portion of A in FIG. 1 according to the present invention;

FIG. 3 is a schematic front view of the structure of the present invention.

In the figure: the LED lamp comprises a shell 1, an air outlet cover 2, a connecting rod 3, a fan 4, a supporting plate 5, a circuit board 6, an LED luminous body 7, a storage battery 8, a clamping hole 9, a fixing pipe 10, a spring 11, a clamping rod 12, a long hole 13, a vertical rod 14, a temperature sensor 15, a controller 16, a lamp cover 17, a positioning rod 18 and a heat conducting plate 19.

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.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be configured in a specific orientation, and operate, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, such as "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The shell 1, the air outlet cover 2, the connecting rod 3, the fan 4, the supporting plate 5, the circuit board 6, the LED luminous body 7, the storage battery 8, the clamping hole 9, the fixing pipe 10, the spring 11, the clamping rod 12, the long hole 13, the vertical rod 14, the temperature sensor 15, the controller 16, the lamp shade 17, the positioning rod 18 and the heat conducting plate 19 are all universal standard parts or parts known by a person skilled in the art, and the structure and the principle of the invention can be known by technical manuals or conventional experimental methods.

Referring to fig. 1-3, an LED infrared sensing lamp with emergency function comprises a housing 1, a gas outlet cover 2 is threaded on the top of the housing 1, a connecting rod 3 is fixedly connected to both sides of the bottom of the gas outlet cover 2, a fan 4 is fixedly connected to one end of the connecting rod 3 away from the gas outlet cover 2, a supporting plate 5 is fixedly connected to both sides of the housing 1, a circuit board 6 is placed on the top of the supporting plate 5, an LED light emitting body 7 is fixedly connected to the bottom of the circuit board 6, a storage battery 8 is disposed on the top of the circuit board 6, a clamping hole 9 is formed in the bottom of each side of the housing 1, a fixing tube 10 is fixedly connected to both sides of the top of the circuit board 6, a spring 11 is fixedly connected to the inner wall of the fixing tube 10, a clamping rod 12 is fixedly connected to one side of the spring 11 away from the inner wall of the fixing tube 10, the top of the clamping rod 12 is fixedly connected with a vertical rod 14, the top of the vertical rod 14 penetrates through a long hole 13 and extends to the inner cavity of the shell 1, the top of the circuit board 6 and the front side of the storage battery 8 are respectively and fixedly connected with a temperature sensor 15 and a controller 16, the bottom of the shell 1 is fixedly connected with a lampshade 17, the clamping rod 12 is tensioned by arranging a spring 11, the clamping rod 12 is enabled to extend into the inner cavity of the clamping hole 9, so that the circuit board 6 is fixedly installed, the clamping rod 12 is conveniently driven to transversely move and be away from the clamping hole 9 by arranging the vertical rod 14, the circuit board 6 is conveniently disassembled, the inner cavity of the shell 1 is conveniently communicated with outside air by arranging the air outlet cover 2, positioning rods 18 are fixedly connected to both sides of the bottom of the circuit board 6, positioning holes are formed in the top of the supporting plate 5, the bottoms of the positioning rods 18 extend to the inner cavities of the positioning holes, and the supporting plate 5 and the positioning holes are formed by arranging the positioning rods 18, can fix a position the support to circuit board 6, be convenient for the installation of circuit board 6, the surface of casing 1 runs through and is provided with heat-conducting plate 19, one side of heat-conducting plate 19 runs through casing 1 and extends to the inner chamber of casing 1, through setting up heat-conducting plate 19, can absorb the heat of casing 1 inner chamber, and wear the heat to lead to the outside, be convenient for thermal giveaway, battery 8's both sides all are provided with the flexure strip, one side fixedly connected with locating plate that battery 8 was kept away from to the flexure strip, the bottom and the circuit board 6 fixed connection of locating plate, through setting up the flexure strip, can be with battery 8 electrically conductive end in close contact with, be convenient for the stable installation of battery 8, the output of temperature sensor 15 and controller 16 electric connection, controller 16 and fan 4, LED luminous element 7 electric connection, through casing 1, play gas hood 2, connecting rod 3, fan 4, backup pad 5, circuit board 6, LED luminous element 7, the battery 8, card hole 9, fixed pipe 10, spring 11, kelly 12, slot hole 13, the montant 14, temperature sensor 15 and controller 16 cooperate, possess and use through the emergent power supply of battery 8, automatic heat dissipation, long service life's advantage, it does not have emergent function to have solved current LED infrared induction lamp, will unable use under the condition of having a power failure, can not dispel the heat automatically, at the during operation radiating efficiency low, seriously influence the life of self, use cost's problem has been increased.

During the use, when having a power failure, supply power to it through battery 8, play emergent function, temperature sensor 15 detects the temperature of circuit board 6 and the 1 inner chamber of casing, and feed back information to controller 16, when the temperature is greater than the default, controller 16 control fan 4 operation makes the gas flow, with the 1 quick discharge casing of 1 inner chamber hot-air of casing 1, heat-conducting plate 19 absorbs the heat, conduct the heat to the casing 1 outside, the radiating efficiency is improved, when dismantling circuit board 6, rotatory

gas outlet cover

2 and 1 threaded connection of casing, make gas outlet cover 2 and casing separation, remove 14 drive card pole 12 lateral shifting of removal montant, make card pole 12 keep away from card hole 9, upward movement circuit board 6 takes out casing 1, thereby be convenient for maintain and change the battery to circuit board 6.

In summary, the following steps: this LED infrared induction lamp with emergent function, through casing 1, venthole 2, connecting rod 3, fan 4, backup pad 5, circuit board 6, LED luminous element 7, battery 8, card hole 9, fixed pipe 10, spring 11, kelly 12, slot hole 13, montant 14, temperature sensor 15 and controller 16 cooperate, it does not have emergent function to have solved current LED infrared induction lamp, will not use under the condition that has a power failure, can not dispel the heat automatically, at the during operation radiating efficiency low, seriously influence the life of self, use cost's problem has been increased.

In a more specific implementation, the controller 16 is electrically connected to the upper computer through a communication circuit; the host computer be used for through the stability of electric wire netting and temperature control parameter come the timely early warning information of feedback and send early warning control signal to the controller in order to instruct the controller to make early warning action instruction, early warning action instruction include controller control LED luminous element 7 stroboscopic in order to remind the user to close the power to if still detect LED luminous element 7 and have operating current then controller control LED luminous element 7 is closed by oneself after reminding many times.

In the implementation, the upper computer feeds back timely early warning information through the stability of the power grid and temperature control parameters and sends an early warning control signal to the controller to guide the controller to make an early warning action instruction, the upper computer sends an early warning control signal to the controller and guides the controller to make an early warning action instruction when the stability of the power grid and the temperature control parameters reach early warning conditions, for example, the controller controls the LED luminous body 7 to strobe to remind a user to turn off the power supply, if after a plurality of reminders the LED luminary 7 is still detected to have an operating current, the controller controls the LED luminary 7 to turn itself off, wherein the pre-warning condition, such as, imminent lightning or serious problems with the operation of the grid may lead to damage to the LED luminary 7, or, the temperature control parameter indicates that the ambient environment of the LED illuminator 7 and the temperature thereof are too high, which may cause a line fault or damage to the LED illuminator 7.

In more specific implementation, the upper computer comprises a management unit, a power grid stability evaluation unit, a temperature control parameter learning unit, a temperature control early warning unit and a power grid early warning unit which are connected,

In implementation, a management unit of the upper computer is used for coordinating and scheduling the work of other units, a software system of a server or a pc is adopted in the preferred embodiment of the upper computer, the management unit, the power grid stability evaluation unit, the temperature control parameter learning unit, the temperature control early warning unit and the power grid early warning unit are preferably provided with corresponding software modules, and a wireless communication module circuit is preferably provided for a communication circuit of the upper computer and the controller 16. In specific implementation, the temperature control early warning unit acquires heat generation energy efficiency of at least one cycle in the future at any moment for evaluation, and sends early warning data to the management unit when the heat generation energy efficiency result exceeds a threshold value so as to trigger the management unit to send an early warning control signal to the controller to guide the controller to make an early warning action instruction;

the power grid early warning unit acquires the stability of at least one period of the power grid in the future all the time to evaluate, and sends early warning data to the management unit when the evaluation result exceeds a threshold value so as to trigger the management unit to send an early warning control signal to the controller to guide the controller to make an early warning action instruction.

The power grid stability evaluation unit provides historical data of a power grid and environmental data such as thunder and lightning for the power grid early warning unit, the temperature control parameter learning unit provides historical data of temperature control parameters and current temperature control parameter data for the temperature control early warning unit, the management unit also waits for early warning data of the power grid early warning unit or the temperature control early warning unit to trigger the management unit to send an early warning control signal to the controller to guide the controller to make an early warning action instruction, in the case that the early warning action instruction needs to be made, the controller controls the LED luminous body 7 to strobe to remind a user to turn off a power supply, if the LED luminous body 7 still detects working current after multiple reminding, the controller controls the LED luminous body 7 to turn off automatically, the early warning data which is waited by the management unit and sent by the power grid early warning unit or the temperature control early warning unit to trigger the management unit to send the early warning control signal to the controller is specifically when a heat production energy efficiency evaluation result of at least one period in the future exceeds a threshold value or the power grid exceeds the threshold value Data when the stability assessment result of at least one period in the future exceeds a threshold value, and the data correspond to: in the case that lightning is about to occur or a serious problem occurs in the operation of the power grid and the LED light emitter 7 may be damaged, the stability evaluation result of at least one future cycle of the power grid may be triggered to exceed the threshold, or the temperature control parameter indicates that conditions such as line fault or damage to the LED light emitter 7 may be triggered by conditions such as an excessively high temperature of the environment around the LED light emitter 7, so that the heat generation energy efficiency evaluation result of at least one cycle exceeds the threshold, specifically, the heat generation energy efficiency evaluation result of at least one cycle of the LED light emitter 7 exceeds the threshold in the present invention.

Therefore, in implementation, the invention can feed back timely early warning information through the upper computer based on the stability of the power grid and temperature control parameters and send early warning control signals to the controller to guide the controller to make early warning action instructions, and can prevent the led luminous body from being damaged in emergency situations.

In a more specific implementation, the obtaining of the historical data of the temperature control parameter and the current temperature control parameter data to evaluate the heat generation energy efficiency of the LED light emitter in at least one future cycle specifically includes: the method comprises the steps of firstly obtaining historical data of temperature control parameters, wherein the historical data of the temperature control parameters comprise historical collected data of a temperature sensor 15 and control data of a simultaneous controller 16, establishing a historical temperature change reference function through the historical collected data of the temperature sensor 15, then singly establishing a control intervention function based on the control data of the simultaneous controller 16, convolving the control intervention function and the temperature change reference function to obtain a comprehensive equivalent temperature control function, reconfiguring the comprehensive equivalent temperature control function in the historical data updating of the temperature control parameters, and then inputting current temperature control parameter data by using the comprehensive equivalent temperature control function to evaluate the heat production energy efficiency of at least one period of an LED luminous body in the future, wherein the evaluation result is an output numerical value of the comprehensive equivalent temperature control function. In implementation, the invention provides a scientific method for evaluating the heat generation energy efficiency of the LED luminous body in at least one future period by acquiring historical data of the temperature control parameters and current temperature control parameter data, and the heat generation energy efficiency of the LED luminous body in at least one future period can be effectively evaluated.

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

1. The utility model provides a LED infrared induction lamp with emergent function, includes casing (1), its characterized in that: the top of the shell (1) is provided with an air outlet cover (2) in a threaded sleeve manner, connecting rods (3) are fixedly connected to two sides of the bottom of the air outlet cover (2), one end, away from the air outlet cover (2), of each connecting rod (3) is fixedly connected with a fan (4), supporting plates (5) are fixedly connected to the bottoms of two sides of the shell (1), a circuit board (6) is placed at the top of each supporting plate (5), a LED luminous body (7) is fixedly connected to the bottom of the circuit board (6), a storage battery (8) is arranged at the top of the circuit board (6), clamping holes (9) are formed in the bottoms of two sides of the shell (1), fixing pipes (10) are fixedly connected to two sides of the top of the circuit board (6), springs (11) are fixedly connected to the inner walls of the fixing pipes (10), and clamping rods (12) are fixedly connected to one sides, away from the inner walls of the fixing pipes (10), of the springs (11), the one end that spring (11) was kept away from in kelly (12) extends to the inner chamber in card hole (9), slot hole (13) have been seted up at the top of fixed pipe (10), the top fixedly connected with montant (14) of kelly (12), the inner chamber that slot hole (13) and extended to casing (1) is run through at the top of montant (14), the top of circuit board (6) and the front side that is located battery (8) fixedly connected with temperature sensor (15) and controller (16) respectively, the bottom fixedly connected with lamp shade (17) of casing (1).

2. The LED infrared induction lamp with the emergency function according to claim 1, characterized in that: the positioning device is characterized in that positioning rods (18) are fixedly connected to two sides of the bottom of the circuit board (6), positioning holes are formed in the top of the supporting plate (5), and the bottoms of the positioning rods (18) extend to inner cavities of the positioning holes.

3. The LED infrared induction lamp with the emergency function according to claim 1, characterized in that: the surface of casing (1) is run through and is provided with heat-conducting plate (19), one side of heat-conducting plate (19) runs through casing (1) and extends to the inner chamber of casing (1).

4. The LED infrared induction lamp with the emergency function according to claim 1, characterized in that: the both sides of battery (8) all are provided with the flexure strip, and the one side fixedly connected with locating plate of battery (8) is kept away from to the flexure strip, the bottom and circuit board (6) fixed connection of locating plate.

5. The LED infrared induction lamp with the emergency function according to claim 1, characterized in that: the output end of the temperature sensor (15) is electrically connected with the controller (16), and the controller (16) is electrically connected with the fan (4) and the LED luminous body (7).

6. The LED infrared induction lamp with the emergency function according to claim 5, characterized in that:

the controller (16) is electrically connected with the upper computer through a communication circuit; the upper computer be used for through the stability of electric wire netting and temperature control parameter come the timely early warning information of feedback and send early warning control signal to the controller in order to instruct the controller to make early warning action instruction, early warning action instruction include controller control LED luminous element (7) stroboscopic in order reminding the user to close the power to if still detect LED luminous element (7) have operating current then controller control LED luminous element (7) self-closing after reminding many times.

7. The LED infrared induction lamp with the emergency function according to claim 6, characterized in that:

the upper computer comprises a management unit, a power grid stability evaluation unit, a temperature control parameter learning unit, a temperature control early warning unit and a power grid early warning unit which are connected,

8. The LED infrared induction lamp with the emergency function according to claim 7, characterized in that:

the obtaining of the historical data of the temperature control parameters and the current temperature control parameter data to evaluate the heat generation energy efficiency of the LED luminary in at least one future cycle specifically includes: the method comprises the steps of firstly obtaining historical data of temperature control parameters, wherein the historical data of the temperature control parameters comprise historical collected data of a temperature sensor (15) and control data of a simultaneous controller (16), establishing a historical temperature change reference function through the historical collected data of the temperature sensor (15), then singly establishing a control intervention function based on the control data of the simultaneous controller (16), convolving the control intervention function and the temperature change reference function to obtain a comprehensive equivalent temperature control function, reconfiguring the comprehensive equivalent temperature control function in the historical data updating of the temperature control parameters, and then inputting current temperature control parameter data by using the comprehensive equivalent temperature control function to evaluate the heat production energy efficiency of at least one period of the future of the LED luminous body, wherein the evaluation result is an output numerical value of the comprehensive equivalent temperature control function.