1. An intelligent design method for an LED lamp scheme is characterized by comprising the following steps:

acquiring power and luminous flux required by a lamp to be designed, and acquiring the lighting effect of the lamp to be designed according to the power and the luminous flux;

obtaining the efficiency of a product controller of a lamp to be designed and measuring the optical transmittance of a lamp bead to obtain the lighting effect of the lamp bead;

acquiring the power of the lamp bead according to the lighting effect of the lamp bead, and acquiring the voltage and the working current of the lamp bead according to the power of the lamp bead;

acquiring the total power of all the lamp beads according to the power of the lamp beads and the efficiency of the lamp to be designed, and further acquiring the number of the required lamp beads;

determining the connection relation of the lamp beads according to the number of the lamp beads, and finally obtaining the output voltage and current of the controller power supply to obtain a design scheme of the lamp to be designed;

and testing the product by using the photoelectric testing equipment to obtain actual product parameters, comparing the actual product parameters with the data in the design scheme, and adjusting the design scheme according to the comparison result.

2. The intelligent design method for the LED lamp scheme according to claim 1, characterized in that: obtain the efficiency of the product controller of treating design lamps and lanterns and measure lamp pearl optical transmittance, still include after the light efficiency that reachs the lamp pearl:

and establishing a device database, and collecting and storing the measured parameters of the optical device in the device database.

3. The intelligent design method for the LED lamp scheme according to claim 1, characterized in that: obtain the power of lamp pearl according to the light efficiency of lamp pearl, still include before voltage and the operating current who obtains the lamp pearl according to the power of lamp pearl:

measuring the lamp beads, obtaining the change rule of the luminous efficiency of the lamp beads along with the power, and drawing the change rule into a power luminous efficiency relation graph;

and measuring the lamp beads, obtaining the change rule between the current and the power of the lamp beads, and drawing the change rule into a current-power relation graph.

4. The intelligent design method for the LED lamp scheme according to claim 1, characterized in that: according to the power of lamp pearl and the efficiency of treating the design lamps and lanterns, obtain the total power of whole lamp pearls, and then still include after reacing the quantity of required lamp pearl:

detecting whether the number of required lamp beads is an integer;

when the number of the required lamp beads is an integer, the original result is reserved;

and when the number of the required lamp beads is not an integer, supplementing the number of the required lamp beads into the integer by adopting a further method, and updating the number of the required lamp beads into the supplemented number.

5. The intelligent design method for the LED lamp scheme according to claim 1, characterized in that: the method for testing the product by using the photoelectric testing equipment to obtain the actual product parameters, comparing the actual product parameters with the data in the design scheme, and adjusting the design scheme according to the comparison result further comprises the following steps:

acquiring an adjusted new design scheme, testing the new design scheme by using photoelectric testing equipment to acquire new actual product parameters, and then comparing the new actual product parameters with data in the new design scheme;

if the comparison result is in line, outputting a final lamp design scheme;

if the comparison result is not in accordance, the design scheme is adjusted again and the steps are repeated.

6. An LED light fixture scheme intelligent design system, the system comprising:

the lighting effect obtaining module (1) is used for obtaining the power and luminous flux required by the lamp to be designed and obtaining the lighting effect of the lamp to be designed according to the power and the luminous flux;

the lighting effect decomposition module (2) is used for obtaining the efficiency of a product controller of the lamp to be designed and measuring the optical transmittance of the lamp beads to obtain the lighting effect of the lamp beads;

the lamp bead parameter module (3) is used for acquiring the power of the lamp beads according to the lighting effect of the lamp beads and acquiring the voltage and the working current of the lamp beads according to the power of the lamp beads;

the lamp bead quantity module (4) is used for acquiring the total power of all the lamp beads according to the power of the lamp beads and the efficiency of the lamp to be designed, so that the quantity of the required lamp beads is obtained;

the scheme generation module (5) determines the connection relation of the lamp beads according to the number of the lamp beads, and finally obtains the output voltage and current of the controller power supply to obtain the design scheme of the lamp to be designed;

and the scheme adjusting module (6) is used for testing the product by using the photoelectric testing equipment to obtain actual product parameters, comparing the actual product parameters with data in the design scheme, and adjusting the design scheme according to the comparison result.

7. An intelligent terminal, comprising a memory and a processor, the memory having stored thereon a computer program that can be loaded by the processor and that executes the method according to any one of claims 1 to 5.

8. A computer-readable storage medium, in which a computer program is stored which can be loaded by a processor and which executes the method of any one of claims 1 to 5.

Background

Lamps are the general name of lighting tools and are divided into ceiling lamps, table lamps, wall lamps, floor lamps and the like. Refers to a device capable of transmitting light, distributing and changing the light distribution of a light source, and comprises all the parts except the light source, which are needed for fixing and protecting the light source, and the circuit accessories which are necessary for connecting with a power supply.

As daily consumables, with the progress of economic society in our country, lighting fixtures gradually change from the original single practicability to a combination of practicability and decorativeness, and application scenes also change from the daily lighting field to the fields of decoration, scenery and the like. Therefore, the design requirements of the lamp are gradually improved, the lamp with the design defects has large damage to the eyesight of human eyes in the use process, a large number of dangerous factors exist in the use process of inferior lamp products, and the possibility of accident damage caused by the lamp is greatly increased.

In the existing common lamp design method, an engineer generally selects devices and designs circuits in the lamp according to past experience, and tests and adjusts the devices in the design process to finally obtain a lamp design scheme.

In view of the above-mentioned related technologies, the inventor believes that there is a defect that efficiency is low in lamp design work due to the fact that a lamp is tested and adjusted in the lamp design process.

Disclosure of Invention

In order to improve the standardization of lamp design, reduce the detection steps in the design process and further improve the efficiency of lamp design work, the application provides an intelligent design method and system for an LED lamp scheme.

In a first aspect, the present application provides an intelligent design method for an LED lamp scheme, which adopts the following technical scheme:

an intelligent design method for an LED lamp scheme is characterized by comprising the following steps:

acquiring power and luminous flux required by a lamp to be designed, and acquiring the lighting effect of the lamp to be designed according to the power and the luminous flux; obtaining the efficiency of a product controller of a lamp to be designed and measuring the optical transmittance of a lamp bead to obtain the lighting effect of the lamp bead; acquiring the power of the lamp bead according to the lighting effect of the lamp bead, and acquiring the voltage and the working current of the lamp bead according to the power of the lamp bead; acquiring the total power of all the lamp beads according to the power of the lamp beads and the efficiency of the lamp to be designed, and further acquiring the number of the required lamp beads; determining the connection relation of the lamp beads according to the number of the lamp beads, and finally obtaining the output voltage and current of the controller power supply to obtain a design scheme of the lamp to be designed; and testing the product by using the photoelectric testing equipment to obtain actual product parameters, comparing the actual product parameters with the data in the design scheme, and adjusting the design scheme according to the comparison result.

By adopting the technical scheme, according to the basic parameters of the target product to be designed, the detail parameters related in the lamp design scheme and the connection mode of the device are reversely deduced, so that the detail parameters in the lamp design scheme can be based on a calculation formula and are attached to the basic parameters of the target product, the accuracy of the lamp design scheme is improved, repeated detection and adjustment in the design process are not needed, the product is uniformly detected after the lamp design scheme is completed, the steps of detecting the lamp or the device are reduced, and the working efficiency of the lamp design scheme is improved while the design normalization of the lamp design scheme is improved.

Optionally, obtain the efficiency of the product controller of lamps and lanterns of treating design and measure lamp pearl optical transmittance, still include after the light efficiency that reachs the lamp pearl:

and establishing a device database, and collecting and storing the measured parameters of the optical device in the device database.

By adopting the technical scheme, after optical devices such as lamp beads and the like are detected, the detection result is collected and matched with the detected optical devices, so that when the lamp is required to be designed, the used lamp beads can be retrieved from the device database and the stored parameters can be directly used, the situation of repeated measurement of the optical devices which are repeatedly used for many times is reduced, and the efficiency of lamp design work is improved.

Optionally, obtain the power of lamp pearl according to the light efficiency of lamp pearl, still include before voltage and the operating current of obtaining the lamp pearl according to the power of lamp pearl:

measuring the lamp beads, obtaining the change rule of the luminous efficiency of the lamp beads along with the power, and drawing the change rule into a power luminous efficiency relation graph;

and measuring the lamp beads, obtaining the change rule between the current and the power of the lamp beads, and drawing the change rule into a current-power relation graph.

Through adopting above-mentioned technical scheme, under the condition that obtains the light efficiency of lamp pearl, detect the photoelectric property of lamp pearl, acquire the power light efficiency relational graph and the electric current power relational graph of lamp pearl, and then compare the light efficiency and the power light efficiency relational graph of lamp pearl in the lamps and lanterns design scheme, acquire the power of lamp pearl, compare the power and the electric current power relational graph of lamp pearl, acquire the operating current and the voltage of lamp pearl, the mode of random debugging has been replaced, design the electric current and the voltage of lamp pearl with the parameter as the benchmark, the operating current and the voltage design's of lamp pearl rationality has been improved, the work load of detecting the adjustment has been reduced, and then the efficiency of lamps and lanterns design work has been improved.

Optionally, the total power of all the lamp beads is obtained according to the power of the lamp beads and the efficiency of the lamp to be designed, and then the number of the required lamp beads is obtained, and the method further comprises the following steps:

detecting whether the number of required lamp beads is an integer;

when the number of the required lamp beads is an integer, the original result is reserved;

and when the number of the required lamp beads is not an integer, supplementing the number of the required lamp beads into the integer by adopting a further method, and updating the number of the required lamp beads into the supplemented number.

Through adopting above-mentioned technical scheme for the result laminating actual conditions of lamps and lanterns design scheme, avoid appearing the condition that lamp pearl quantity is not the integer in the lamps and lanterns design scheme, strengthened lamps and lanterns design scheme's rationality, to the condition that lamp pearl quantity is not the integer, adopt one-in-one to handle, make the total light efficiency of lamp pearl be more than or equal to the required light efficiency of lamps and lanterns design, the product that has reduced lamps and lanterns design scheme corresponds can't satisfy the possibility that the condition that product design required appears, and then improved lamps and lanterns design scheme's quality.

Optionally, the testing the product by using the optoelectronic testing device to obtain actual product parameters, comparing the actual product parameters with data in the design scheme, and adjusting the design scheme according to the comparison result further includes:

acquiring an adjusted new design scheme, testing the new design scheme by using photoelectric testing equipment to acquire new actual product parameters, and then comparing the new actual product parameters with data in the new design scheme;

if the comparison result is in line, outputting a final lamp design scheme;

if the comparison result is not in accordance, the design scheme is adjusted again and the steps are repeated.

By adopting the technical scheme, the lamp design scheme is detected, so that the corresponding product in the lamp design scheme can be compared with the target product, the possibility that the product generated by the lamp design scheme meets the requirement is enhanced, the lamp design scheme is subjected to adjustment-detection cycle, the fitting degree of the finally generated lamp design scheme and the target product is improved, and the quality of the lamp design scheme is improved while the efficiency of generating the lamp design scheme is improved.

In a second aspect, the present application provides an intelligent design system for an LED lamp solution, which adopts the following technical solution:

an LED luminaire solution intelligent design system, said system comprising:

the lighting effect obtaining module is used for obtaining power and luminous flux required by the lamp to be designed and obtaining the lighting effect of the lamp to be designed according to the power and the luminous flux;

the lighting effect decomposition module is used for obtaining the efficiency of a product controller of the lamp to be designed and measuring the optical transmittance of the lamp beads to obtain the lighting effect of the lamp beads;

the lamp bead parameter module is used for acquiring the power of the lamp beads according to the lighting effect of the lamp beads and acquiring the voltage and the working current of the lamp beads according to the power of the lamp beads;

the lamp bead quantity module is used for acquiring the total power of all the lamp beads according to the power of the lamp beads and the efficiency of the lamp to be designed, so that the quantity of the required lamp beads is obtained;

the scheme generation module determines the connection relation of the lamp beads according to the number of the lamp beads, and finally obtains the output voltage and current of the controller power supply to obtain the design scheme of the lamp to be designed;

and the scheme adjusting module is used for testing the product by using the photoelectric testing equipment to obtain actual product parameters, comparing the actual product parameters with data in the design scheme and adjusting the design scheme according to a comparison result.

By adopting the technical scheme, according to the basic parameters of the target product to be designed, the detail parameters related in the lamp design scheme and the connection mode of the device are reversely deduced, so that the detail parameters in the lamp design scheme can be based on a calculation formula and are attached to the basic parameters of the target product, the accuracy of the lamp design scheme is improved, repeated detection and adjustment in the design process are not needed, the product is uniformly detected after the lamp design scheme is completed, the steps of detecting the lamp or the device are reduced, and the working efficiency of the lamp design scheme is improved while the design normalization of the lamp design scheme is improved.

In a third aspect, the present application provides an intelligent terminal, which adopts the following technical scheme:

an intelligent terminal comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and can execute the method.

By adopting the technical scheme, the processor in the intelligent terminal can realize the intelligent design method of the LED lamp scheme according to the related computer program stored in the memory, so that the design standardization of the lamp is improved, the detection steps in the design process are reduced, and the design work efficiency of the lamp is improved.

In a fourth aspect, the present application provides a computer-readable storage medium, which adopts the following technical solutions:

a computer-readable storage medium storing a computer program that can be loaded by a processor and executes the above-mentioned method.

By adopting the technical scheme, corresponding programs can be stored, so that the standardization of lamp design is improved, the detection steps in the design process are reduced, and the efficiency of lamp design work is improved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. according to basic parameters of a target product to be designed, detail parameters related in a lamp design scheme and a connection mode of a device are reversely deduced, so that the detail parameters in the lamp design scheme can be matched with the basic parameters of the target product on the basis of a calculation formula, the accuracy of the lamp design scheme is improved, repeated detection and adjustment are not needed in the design process, the product is uniformly detected after the lamp design scheme is finished, the steps of detecting the lamp or the device are reduced, and the working efficiency of lamp design scheme design is improved while the design normalization of the lamp design scheme is improved;

2. after optical devices such as lamp beads and the like are detected, the detection result is collected and matched with the detected optical devices, so that when the lamp is required to be designed, the used lamp beads can be retrieved from the device database and the stored parameters can be directly used, the situation of repeatedly measuring the optical devices which are repeatedly used for many times is reduced, and the efficiency of lamp design work is further improved;

3. the lamp design scheme is detected, so that a corresponding product in the lamp design scheme can be compared with a target product, the possibility that the product generated by the lamp design scheme meets requirements is enhanced, the lamp design scheme is subjected to adjustment-detection cycle, the fitting degree of the finally generated lamp design scheme and the target product is improved, the efficiency of generating the lamp design scheme is improved, and meanwhile, the quality of the lamp design scheme is improved.

Drawings

Fig. 1 is a block flow diagram of an intelligent design method of an LED lamp solution shown in an embodiment of the present application;

fig. 2 is a power-light effect relationship diagram in an intelligent design method of an LED lamp solution shown in an embodiment of the present application;

FIG. 3 is a current-power relationship diagram in an intelligent design method of an LED lamp solution shown in the embodiment of the present application;

fig. 4 is a system block diagram of an intelligent design system of an LED lamp solution shown in an embodiment of the present application.

Description of reference numerals: 1. a light effect obtaining module; 2. a light effect decomposition module; 3. a lamp bead parameter module; 4. a lamp bead number module; 5. a scheme generation module; 6. and a scheme adjusting module.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

Example (b):

the embodiment of the application discloses an intelligent design method for an LED lamp scheme.

Referring to fig. 1, an intelligent design method for an LED lamp scheme includes the following steps:

s100, acquiring power and luminous flux required by a lamp to be designed, and acquiring the lighting effect of the lamp to be designed according to the power and the luminous flux;

specifically, the light efficiency of the lamp to be designed is calculated according to the following formula:

LPW₁=￠₁/P₁

wherein, LPW₁For the luminous efficacy of the lamp to be designed, P₁Phi for the total power of the lamp to be designed₁Is the luminous flux.

S200, obtaining the efficiency of a product controller of a lamp to be designed and measuring the optical transmittance of a lamp bead to obtain the lighting effect of the lamp bead;

specifically, the product controller efficiency and the optical transmittance of the lamp beads are obtained by referring to the product specifications of the selected product controller and the lamp beads, and then the lighting effect of the lamp beads is measured and calculated, wherein the specific calculation formula is as follows:

LPW₂=LPW₁/ŋ₁/ŋ₂

wherein, LPW₂Light efficiency of lamp beads, ŋ₁For controller efficiency, ŋ₂Is the optical transmittance of the lamp beads.

And then establishing a device database, partitioning the device database into a controller library and a lamp bead library, storing parameters such as light efficiency of the selected lamp beads and the lamp beads into the lamp bead library, storing parameters such as efficiency of the controller and the controller into the controller library, and facilitating retrieval and calling.

Adopt photoelectric detection equipment to detect the lamp pearl, it is specific: inputting gradient changing power to the lamp beads, detecting the luminous efficiency of the lamp beads, drawing a power luminous efficiency relation graph, referring to fig. 2, wherein the horizontal axis is power, and the vertical axis is luminous efficiency, then recording the measured luminous efficiency and power data of the lamp beads in the power luminous efficiency relation graph, and removing noise points in the measurement results, wherein the noise points are specifically measurement points with great difference with the measurement results in the power luminous efficiency relation graph of the lamp beads;

adopt electrical property check out test set to detect the lamp pearl, it is specific: inputting current with gradient change to the lamp beads, calculating to obtain the voltage of the lamp beads, further obtaining the impedance of the lamp beads, obtaining the power of the lamp beads through the current and the impedance of the lamp beads, drawing the calculation result to form a current-power relation graph, wherein the horizontal axis is the voltage, and the vertical axis is the current.

S300, acquiring power of the lamp beads according to the lighting effect of the lamp beads, and acquiring voltage and working current of the lamp beads according to the power of the lamp beads;

the relation between the power of the lamp bead and the voltage and the current is specifically as follows:

P₂=U₂*I₂

wherein, U₂Voltage for a single lamp bead, I₂Current of a single lamp bead, P₂The power of a single lamp bead.

S400, acquiring the total power of all lamp beads according to the power of the lamp beads and the efficiency of the lamp to be designed, and further obtaining the number of the required lamp beads;

specifically, the total power of the lamp beads is calculated according to the power and efficiency of the lamp to be designed, and the calculation formula is as follows:

P_T=P₁* ŋ₁

wherein, P_TThe total power of the lamp beads;

then, according to the total power of all the lamp beads, the number of the lamp beads is calculated, and the calculation formula is as follows:

N=P_T/P₂

wherein N is the number of the lamp beads;

detecting whether the number of required lamp beads is an integer; when the number of the required lamp beads is an integer, the original result is reserved; and when the number of the required lamp beads is not an integer, supplementing the number of the required lamp beads into the integer by adopting a further method, and updating the number of the required lamp beads into the supplemented number.

For example, when the number of the calculated lamp beads is 10, the result is retained; when the calculated number of the lamp beads is 10.5, the number of the lamp beads finally output after one lamp bead is 11.

S500, determining the connection relation of the lamp beads according to the number of the lamp beads, and finally obtaining the output voltage and current of the controller power supply to obtain a design scheme of the lamp to be designed;

wherein, the relation of connection of lamp pearl specifically is the series connection parallel relation, embodies for participating in the lamp pearl quantity of establishing ties and participating in parallelly connected lamp pearl quantity, and specific computational formula is as follows:

N=S_N*P_N

S_Nis the number of lamp beads connected in series, P_NThe number of the lamp beads connected in parallel is adopted;

according to the serial connection and parallel connection quantity of the lamp beads, the output voltage Uo and the current Io of the power supply of the controller are selected, and the calculation formula is as follows:

Uo=S_N*U₂

Io=P_N*I₂

s600, testing the product by using photoelectric testing equipment to obtain actual product parameters, comparing the actual product parameters with data in a design scheme, and adjusting the design scheme according to a comparison result;

then obtaining the adjusted new design scheme, testing the new design scheme by using photoelectric testing equipment to obtain new actual product parameters, and then comparing the new actual product parameters with data in the new design scheme;

if the comparison result is in line, outputting a final lamp design scheme;

if the comparison result does not match, the design scheme is adjusted again and the step S600 is repeated.

Based on the above method, the embodiment of the present application further discloses an intelligent design system for an LED lamp solution, with reference to fig. 4, including:

the lighting effect obtaining module 1 is used for obtaining power and luminous flux required by a lamp to be designed and obtaining the lighting effect of the lamp to be designed according to the power and the luminous flux;

the lighting effect decomposition module 2 is used for obtaining the efficiency of a product controller of the lamp to be designed and measuring the optical transmittance of the lamp beads to obtain the lighting effect of the lamp beads;

the lamp bead parameter module 3 is used for acquiring the power of the lamp bead according to the lighting effect of the lamp bead and acquiring the voltage and the working current of the lamp bead according to the power of the lamp bead;

the lamp bead quantity module 4 is used for acquiring the total power of all the lamp beads according to the power of the lamp beads and the efficiency of the lamp to be designed, so as to obtain the quantity of the required lamp beads;

the scheme generation module 5 determines the connection relation of the lamp beads according to the number of the lamp beads, and finally obtains the output voltage and current of the controller power supply to obtain the design scheme of the lamp to be designed;

and the scheme adjusting module 6 is used for testing the product by using the photoelectric testing equipment to obtain actual product parameters, comparing the actual product parameters with data in the design scheme, and adjusting the design scheme according to the comparison result.

The embodiment of the application also discloses an intelligent terminal, which comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and can execute the intelligent design method of the LED lamp scheme.

The embodiment of the present application further discloses a computer-readable storage medium, which stores a computer program that can be loaded by a processor and execute the above-mentioned LED lamp scheme intelligent design method, and the computer-readable storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The above examples are only used to illustrate the technical solutions of the present application, and do not limit the scope of protection of the application. It is to be understood that the embodiments described are only some of the embodiments of the present application and not all of them. All other embodiments, which can be derived by a person skilled in the art from these embodiments without making any inventive step, are within the scope of the present application.