CN209893662U - Light energy processing device - Google Patents

Abstract

The application provides a light energy processing device, which is applied to deserts and comprises a processing assembly, a lighting assembly, a moving device, a high-temperature sensor and an alarm, wherein the die comprises an accommodating cavity for accommodating materials; the lighting assembly is used for melting the collected sunlight on the material; the high-temperature type temperature sensor is used for detecting whether the temperature of a light spot formed by a high-temperature light beam on a material is greater than or equal to a preset temperature or not; the alarm is used for giving an alarm when the temperature of the light spot is detected to be lower than the preset temperature; the photoelectric conversion assembly comprises a lighting power generation assembly and a control assembly, the lighting power generation assembly and the mobile device are respectively coupled with the control assembly, and the lighting power generation assembly is used for collecting sunlight and converting the light energy of the sunlight into electric energy; the control assembly is used for transmitting electric energy to the mobile device and the alarm so as to supply power to the mobile device and the alarm. By the method, the power consumption of the material during sintering by using solar energy can be reduced.

Description

Light energy processing device

Technical Field

The application relates to the technical field of processing of combined energy of photovoltaic power generation and light-gathering and heat-gathering, in particular to a light energy processing device.

Background

Through research of scientists, the land area on the earth is 1.47 hundred million square kilometers, which accounts for 28 percent of the total area of the earth, wherein the desert accounts for 1/3, and the desert also has a sand storm which enables people to smell and thrill. The total area of the deserts in China, including the sand lands in arid and semiarid regions in China, reaches about 130.7 ten thousand square kilometers, and approximately occupies 13.6 percent of the total area of the land in China.

The desert has unique advantages, such as less rain, strong illumination, inexhaustible high-energy, no environmental pollution, more and more high-light energy products, solar traffic signal lamps, solar chargers, solar water heaters, solar power stations and the like, and solar energy technology enters daily life of people from the high-tech field.

The utility model discloses the people discovers in long-term research and development, and the application that utilizes solar technology in material light sintering processing field is still very little, mainly is subject to aspects such as collection, transmission processing of light energy, leads to the facula temperature that obtains to be low, and the degree of convergence is not enough, can not satisfy the requirement in material sintering processing field to still need a large amount of electric energy to maintain the operation of self when adding man-hour.

SUMMERY OF THE UTILITY MODEL

The application provides a light energy processingequipment to utilize solar energy to add the problem that power consumption is big during to the material sintering processing among the solution prior art.

In order to solve the technical problem, the application adopts a technical scheme that: there is provided a light energy processing device for use in deserts, wherein the light energy processing device comprises

The processing assembly comprises a mold, a lighting assembly, a moving device, a high-temperature sensor and an alarm, wherein the mold is arranged on the moving device and comprises an accommodating cavity, the accommodating cavity is in a preset shape, and the accommodating cavity is used for accommodating materials; the lighting assembly is used for gathering sunlight and gathering the gathered sunlight on the accommodating cavity to form high-temperature light beams so as to melt the material; the moving device is used for moving the mould; the high-temperature type temperature sensor is coupled with the alarm, is arranged on the die and is used for detecting whether the temperature of a light spot formed on a material by the high-temperature light beam is greater than or equal to a preset temperature or not; the alarm is arranged on the mobile device and used for giving an alarm when the high-temperature type temperature sensor detects that the temperature of the light spot is lower than the preset temperature; the photoelectric conversion assembly comprises a lighting power generation assembly and a control assembly, the lighting power generation assembly and the mobile device are respectively coupled with the control assembly, and the lighting power generation assembly is used for collecting the sunlight and converting the light energy of the sunlight into electric energy; the control assembly is used for transmitting the electric energy to the mobile device and the alarm so as to supply power to the mobile device and the alarm.

The beneficial effect of this application is: the optical energy processing device comprises a processing assembly, a lighting assembly, a moving device, a high-temperature sensor and an alarm, wherein the processing assembly comprises a mold, a lighting assembly, a moving device, a high-temperature sensor and the alarm; the lighting assembly is used for gathering sunlight and gathering the gathered sunlight on the accommodating cavity to form high-temperature light beams so as to melt the materials; the moving device is used for moving the mould; the high-temperature type temperature sensor is coupled with the alarm, is arranged on the die and is used for detecting whether the temperature of a light spot formed by a high-temperature light beam on a material is greater than or equal to a preset temperature or not; the alarm is arranged on the mobile device and used for giving an alarm when the high-temperature type temperature sensor detects that the temperature of the light spot is lower than a preset temperature; the photoelectric conversion assembly comprises a lighting power generation assembly and a control assembly, the lighting power generation assembly and the mobile device are respectively coupled with the control assembly, and the lighting power generation assembly is used for collecting sunlight and converting the light energy of the sunlight into electric energy; the control assembly is used for transmitting electric energy to the mobile device and the alarm so as to supply power to the mobile device and the alarm. The sunlight is obtained through the lighting assembly, the sunlight is gathered to form high-temperature light beams, the high-temperature light beams can melt materials, and after the lighting power generation assembly obtains the sunlight, the light energy of the sunlight is converted into the electric energy of the work of the light energy processing device, so that the problem of large power consumption in the process of sintering and processing materials by utilizing solar energy in the prior art is solved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the application, the drawings that are needed to be used in the description of the embodiments are briefly introduced below, it is obvious that the drawings in the following description are only some embodiments of the application, and other drawings can be obtained by those skilled in the art without inventive efforts, wherein:

FIG. 1 is a schematic structural diagram of an embodiment of a light energy processing apparatus of the present application;

fig. 2 is a schematic structural diagram of another embodiment of an optical energy processing apparatus according to the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any inventive step based on the embodiments in the present application, are within the scope of protection of the present application.

It should be noted that if directional indications (such as up, down, left, right, front, and back … …) are referred to in the embodiments of the present application, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present application.

Referring to fig. 1, fig. 1 is a schematic structural diagram of an embodiment of a light energy processing device according to the present application. The optical energy processing device 100 disclosed in this embodiment is applied to a desert, and includes a processing module 11 and a photoelectric conversion module 13.

Specifically, the processing assembly 11 includes a mold 111, a lighting assembly 113, a moving device 115, a high-temperature sensor 117, and an alarm 119. The mold 111 is disposed on the moving device 115, and the mold 111 and the moving device 115 may be detachably connected or integrally formed, which is not limited herein. The mold 111 includes a receiving cavity (not shown) having a predetermined shape for receiving a material; the moving device 115 is used to move the mold 111.

The light collecting component 113 is disposed above the mold 111, and is used for collecting sunlight and collecting the collected sunlight on the accommodating cavity to form a high-temperature light beam, so as to melt the material, thereby obtaining a molded building material.

High temperature type temperature sensor 117 and alarm 119 are coupled, and high temperature type temperature sensor 117 sets up on mould 111 for whether the temperature of the facula that detects high temperature light beam formation on the material is greater than or equal to preset temperature. The preset temperature is set according to the melting point of the material added in the accommodating cavity of the mold 111, when the optical energy processing device 100 is applied to a desert, the material may be sand in the desert, the melting point of the sand is about 1700 ℃, and at this time, the preset temperature may be set to be greater than or equal to the melting point of the material, for example, the preset temperature is set to 1800 ℃ in this embodiment. When the temperature of the light spot formed by the high-temperature light beam on the material is greater than or equal to the preset temperature, the temperature of the light spot formed by the high-temperature light beam on the material is greater than the melting point of the material, so that the material can be melted. The molten material is cooled, for example, by removing the high temperature beam, to solidify the material and provide a shaped building material.

Alarm 119 sets up on mobile device 115 for when high temperature type temperature sensor 117 detects the temperature of facula and is less than preset the temperature, report to the police to remind the high temperature light beam temperature that present daylighting subassembly 113 obtained to be less than preset the temperature, the temperature that does not reach the melting material.

The photovoltaic conversion assembly 13 includes a lighting and power generating assembly 131 and a control assembly 133, and the lighting and power generating assembly 131 and the moving device 115 are respectively coupled to the control assembly 133. The lighting power generation assembly 131 is disposed above the control assembly 133, and is configured to collect sunlight and convert light energy of the sunlight into electric energy. Control assembly 133 is used to transmit power to mobile device 115 and alarm 119 to power mobile device 115 and alarm 119.

The application provides a light energy processing device, which is applied to deserts and comprises a processing assembly, a lighting assembly, a moving device, a high-temperature sensor and an alarm, wherein the mold is arranged on the moving device and comprises an accommodating cavity, the accommodating cavity is in a preset shape and is used for accommodating materials; the lighting assembly is used for gathering sunlight and gathering the gathered sunlight on the accommodating cavity to form high-temperature light beams so as to melt the materials; the moving device is used for moving the mould; the high-temperature type temperature sensor is coupled with the alarm, is arranged on the die and is used for detecting whether the temperature of a light spot formed by a high-temperature light beam on a material is greater than or equal to a preset temperature or not; the alarm is arranged on the mobile device and used for giving an alarm when the high-temperature type temperature sensor detects that the temperature of the light spot is lower than a preset temperature; the photoelectric conversion assembly comprises a lighting power generation assembly and a control assembly, the lighting power generation assembly and the mobile device are respectively coupled with the control assembly, and the lighting power generation assembly is used for collecting sunlight and converting the light energy of the sunlight into electric energy; the control assembly is used for transmitting electric energy to the mobile device and the alarm so as to supply power to the mobile device and the alarm. The sunlight is acquired through the lighting assembly, the sunlight is gathered to form high-temperature light beams, the high-temperature light beams can melt materials, after the lighting power generation assembly acquires the sunlight, the light energy of the sunlight is converted into the electric energy of the work of the light energy processing device, the power consumption of the material sintering processing by utilizing solar energy can be reduced, and the limitation of the work place of the light energy processing device can be reduced.

On the basis of the foregoing embodiments, please refer to fig. 2, and fig. 2 is a schematic structural diagram of another embodiment of a light energy processing apparatus according to the present application. The optical energy processing device 100 disclosed in this embodiment is applied to a desert, and includes a processing module 11 and a photoelectric conversion module 13.

Specifically, the processing assembly 11 includes a mold 111, a lighting assembly 113, a moving device 115, a high-temperature type temperature sensor 117, and an alarm 119. The mold 111 is disposed on the moving device 115, and in this embodiment, the mold 111 and the moving device 115 may be detachably connected. The mold 111 includes a receiving cavity (not shown) having a predetermined shape for receiving a material; the moving device 115 is used to move the mold 111. When the optical energy processing device 100 is applied to a desert, the material may be sand in the desert, and when the optical energy processing device is applied to other environments, the material may be solid material such as stone, a mixture of sand and stone, or a mixture of solid material and liquid material.

The light collecting component 113 is disposed above the mold 111, and is used for collecting sunlight and collecting the collected sunlight on the accommodating cavity to form a high-temperature light beam, so as to melt the material, thereby obtaining a molded building material.

High temperature type temperature sensor 117 and alarm 119 are coupled, and high temperature type temperature sensor 117 sets up on mould 111 for whether the temperature of the facula that detects high temperature light beam formation on the material is greater than or equal to preset temperature. The preset temperature is set according to the melting point of the material added in the accommodating cavity of the mold 111, when the optical energy processing device 100 is applied to a desert, the material may be sand in the desert, the melting point of the sand is about 1700 ℃, and at this time, the preset temperature may be set to be greater than or equal to the melting point of the material, for example, the preset temperature is set to 1800 ℃ in this embodiment. When the temperature of the light spot formed by the high-temperature light beam on the material is greater than or equal to the preset temperature, the temperature of the light spot formed by the high-temperature light beam on the material is greater than the melting point of the material, so that the material can be melted. The molten mass is cooled, for example by removing the high temperature beam, to solidify the mass and provide a shaped building material.

Alarm 119 sets up on mobile device 115 for when high temperature type temperature sensor 117 detects the temperature of facula and is less than preset the temperature, report to the police to remind the high temperature light beam temperature that present daylighting subassembly 113 obtained to be less than preset the temperature, the temperature that does not reach the melting material.

In a specific embodiment, the predetermined shape includes at least one of a rectangular parallelepiped, a cube, a prism, a cylinder, and an irregular shape. For example, the user may desire a rectangular parallelepiped building material, melt the material in the processing assembly 11 using a mold 111 having a rectangular parallelepiped housing cavity to form a desired solid building material, and demold the building material in the mold 111 to obtain the building material, and accordingly, the processing assembly 11 may include a demolding device (not shown) provided on the moving device 115 to demold the material solidified in the housing cavity.

In an embodiment, the light collecting assembly 113 includes a support (not shown), a first light concentrating unit 1131 and a second light concentrating unit 1133, the first light concentrating unit 1131 is disposed on the support, the second light concentrating unit 1133 is disposed on a side of the first light concentrating unit 1131 close to the mold 111, the support is hinged to the moving device 115, the first light concentrating unit 1131 is configured to concentrate sunlight and provide a light concentrating factor, and the second light concentrating unit 1133 is configured to form concentrated sunlight into a high temperature light beam. The second condensing unit 1133 can increase the concentration of the sunlight, thereby increasing the temperature of the light spot formed on the material by the condensed sunlight. The sunlight collected by the first light collecting unit 1131 passes through the second light collecting unit 1133 to form a high temperature light beam on the material in the mold 111, and the light spot of the high temperature light beam irradiates the material.

In an embodiment, the first light-gathering unit 1131 includes a plurality of high power optical lenses 11311, and the high power optical lenses 11311 are used for gathering the sunlight and providing the light-gathering power. The number of the high power optical lenses 11311 may be set according to the current sunlight intensity. For example, if the current sunlight intensity is low, the high-temperature type temperature sensor 117 detects that the temperature of a light spot formed by a high-temperature light beam on a material is lower than a preset temperature, the light spot does not reach the melting point of the material, the material cannot be melted, at this moment, the alarm 119 gives an alarm, and after knowing the alarm information, a worker can increase the number of the high-power optical lenses 11311 to increase the light condensation multiple, so that the temperature of the melted material is reached, and the working efficiency of the melted material can be improved; if the current sunlight intensity is higher, the worker can know the temperature fed back by the high-temperature type temperature sensor 117, for example, the optical energy processing apparatus 100 further includes a temperature display unit (not shown) coupled to the high-temperature type temperature sensor 117, and if the high-temperature type temperature sensor 117 detects that the temperature of the light spot formed by the high-temperature light beam on the material is far greater than the preset temperature, that is, far greater than the melting point of the material, the number of the high-power optical lenses 11311 can be reduced to reduce the light-gathering multiple, and the temperature of the melted material can be reached, so that the loss of the high-power optical lenses 11311 can be reduced, and the economic cost can be reduced.

The gathered sunlight forms light spots on the material, and the temperature of the light spots can reach the temperature of the melted material under the condition of different sunlight intensities by adjusting the number of the high power optical lenses 11311.

In a specific embodiment, the first light gathering unit 1131 further includes a sun tracking assembly 11313, the high power optical lens 11311 is disposed on the sun tracking assembly 11313, and the sun tracking assembly 11313 is configured to drive the high power optical lens 11311 to rotate along with the sun according to the irradiation direction of the sunlight.

In an embodiment, the sun-tracking assembly 11313 includes a rotation shaft 113131 and a sunlight sensor 113133, the sunlight sensor 113133 is fixed on the rotation shaft 113131, the high power optical lens 11311 is disposed on the sunlight sensor 113133, the rotation shaft 113131 is disposed on the bracket, the sunlight sensor 113133 is used for tracking the irradiation direction of sunlight, and the rotation shaft 113131 is used for driving the high power optical lens 11311 and the sunlight sensor 113133 to rotate along with the sun.

The sunlight sensor 113133 is used to obtain the irradiation intensity of sunlight.

In one embodiment, the sun-tracking assembly 11313 may further include a solar tracker (not shown) on which the high power optical lens 11311 is disposed and a universal rotating ball (not shown), the solar tracker being configured to track the sun; the universal rotating ball comprises a support (not shown) and a ball body (not shown), the support is arranged on the support and comprises a groove (not shown), the ball body is clamped in the groove and can roll in the groove, the solar tracker is arranged on the ball body, and the ball body is used for driving the high power optical lens 11311 and the solar tracker to rotate along with the sun.

The solar tracker is used for tracking the sun, and an energy collector (not shown), a tracking sensor (not shown), a control unit (not shown) and an indication actuator (not shown) may be disposed in the solar tracker, and the control unit is coupled to the energy collector, the tracking sensor and the indication actuator. The main optical axis of the solar energy collector is always parallel to the solar ray, when the solar ray inclines, the tracking sensor outputs an inclination signal, the signal is amplified and then sent to the control unit, the control unit starts to work, and the actuator is indicated to act to adjust the solar energy collector until the solar energy collector is aligned to the sun.

The sun tracking assembly 11313 enables the first light gathering unit 1131 to have a day-by-day function, and can improve the sunlight gathering capability of the first light gathering unit 1131, so that light spots formed after light gathering are always vertically irradiated on the surface of a material, and the working efficiency of the processing assembly 11 is improved.

The photovoltaic conversion assembly 13 includes a light and power generation assembly 131 and a control assembly 133, and the light and power generation assembly 131 and the moving device 115 are coupled to the control assembly 133. The lighting power generation assembly 131 is disposed above the control assembly 133, and is configured to collect sunlight and convert light energy of the sunlight into electric energy. The control component 133 is used to transmit power to the mobile device 115.

In a specific embodiment, the lighting and power generating assembly 131 includes a plurality of photovoltaic panels 1311, the plurality of photovoltaic panels 1311 are distributed in an array, and a lighting surface of each photovoltaic panel 1311 faces the sun, so that the rays of sunlight irradiate on the lighting surface of the photovoltaic panel 1311.

In one embodiment, the control assembly 133 includes a cpu 1331, a power module 1333 and a driving circuit 1335, the cpu 1331 is coupled to the power module and the driving circuit, and the cpu 1331 is used for controlling the power transmission to the mobile device 115.

In a specific embodiment, the processing assembly 11 further comprises a feeding device 112, the feeding device 112 is disposed on the moving device 115, and the feeding device 112 is used for adding the material to the mold 111; the charging device 112 is further coupled to a control assembly 133, the control assembly 133 further being configured to transmit electrical energy to the charging device 112 to power the charging device 112. The control assembly 133 transmits the electric energy to the moving device 115 and the feeding device 112, so that the moving device 115 drives the mold 111 and the feeding device 112 to move, the building material can be formed at different positions, and the solidified building material can be conveyed to the appointed position by manpower or material resources.

In a specific embodiment, the moving device 115 includes a platform (not shown) and a moving mechanism (not shown), the platform is disposed on the moving mechanism, and the platform is used for carrying the mold 111 and the feeding device 112; the moving mechanism is used for driving the platform to move in the two-dimensional direction, and the formed building materials are conveniently moved to the designated position.

In one embodiment, the moving device 115 may further include a lifting mechanism (not shown) disposed between the platform and the moving mechanism or disposed on a side of the moving mechanism near the ground, wherein the lifting mechanism is configured to lift or lower the platform to move the formed building material to a desired position.

The application provides a light energy processing device, which is applied to deserts and comprises a processing assembly, a lighting assembly, a moving device, a high-temperature sensor and an alarm, wherein the mold is arranged on the moving device and comprises an accommodating cavity, the accommodating cavity is in a preset shape and is used for accommodating materials; the lighting assembly is used for gathering sunlight and gathering the gathered sunlight on the accommodating cavity to form high-temperature light beams so as to melt the materials; the moving device is used for moving the mould; the high-temperature type temperature sensor is coupled with the alarm, is arranged on the die and is used for detecting whether the temperature of a light spot formed by a high-temperature light beam on a material is greater than or equal to a preset temperature or not; the alarm is arranged on the mobile device and used for giving an alarm when the high-temperature type temperature sensor detects that the temperature of the light spot is lower than a preset temperature; the photoelectric conversion assembly comprises a lighting power generation assembly and a control assembly, the lighting power generation assembly and the mobile device are respectively coupled with the control assembly, and the lighting power generation assembly is used for collecting sunlight and converting the light energy of the sunlight into electric energy; the control assembly is used for transmitting electric energy to the mobile device and the alarm so as to supply power to the mobile device and the alarm. Acquire the sunlight through the daylighting subassembly, and gather the sunlight and form high temperature light beam, high temperature light beam can melt the material, whether high temperature type temperature sensor can detect the temperature of the facula of high temperature light beam formation on the material is greater than or equal to and predetermines the temperature, can adjust the daylighting subassembly according to high temperature type temperature sensor's testing result, daylighting power generation subassembly acquires the sunlight after, turn into the electric energy of light energy processingequipment self work with the light energy of sunlight, can reduce the power consumption that utilizes solar energy to material sintering man-hour, can also reduce the restriction in light energy processingequipment workplace.

The above embodiments are merely examples and are not intended to limit the scope of the present disclosure, and all modifications, equivalents, and flow charts using the contents of the specification and drawings of the present disclosure or those directly or indirectly applied to other related technical fields are intended to be included in the scope of the present disclosure.

Claims (10)

1. A light energy processing device applied to deserts is characterized by comprising:

the processing assembly comprises a mold, a lighting assembly, a moving device, a high-temperature sensor and an alarm, wherein the mold is arranged on the moving device and comprises an accommodating cavity, the accommodating cavity is in a preset shape, and the accommodating cavity is used for accommodating materials; the lighting assembly is used for gathering sunlight and gathering the gathered sunlight on the accommodating cavity to form high-temperature light beams so as to melt the material; the moving device is used for moving the mould; the high-temperature type temperature sensor is coupled with the alarm, is arranged on the die and is used for detecting whether the temperature of a light spot formed on a material by the high-temperature light beam is greater than or equal to a preset temperature or not; the alarm is arranged on the mobile device and used for giving an alarm when the high-temperature type temperature sensor detects that the temperature of the light spot is lower than the preset temperature;

the photoelectric conversion assembly comprises a lighting power generation assembly and a control assembly, the lighting power generation assembly and the mobile device are respectively coupled with the control assembly, and the lighting power generation assembly is used for collecting the sunlight and converting the light energy of the sunlight into electric energy; the control assembly is used for transmitting the electric energy to the mobile device and the alarm so as to supply power to the mobile device and the alarm.

2. The light energy processing device according to claim 1, wherein the light collecting assembly comprises a support, a first light concentrating unit and a second light concentrating unit, the first light concentrating unit is disposed on the support, the second light concentrating unit is disposed on a side of the first light concentrating unit close to the mold, the support is hinged to the moving device, the first light concentrating unit is used for concentrating the sunlight and providing a light concentrating multiple, and the second light concentrating unit is used for forming the concentrated sunlight into a high-temperature light beam; the sunlight collected by the first light collecting unit penetrates through the second light collecting unit to form a high-temperature light beam on the material in the mold.

3. The light energy processing device of claim 2 wherein the first concentrating unit comprises a plurality of high power optical lenses for concentrating the sunlight and providing a concentration power.

4. The light energy processing device of claim 3, wherein the first light concentrating unit further comprises a sun tracking assembly, and the high power optical lens is disposed on the sun tracking assembly, and the sun tracking assembly is configured to drive the high power optical lens to rotate along with the sun according to the irradiation direction of the sunlight.

5. The optical energy processing apparatus as claimed in claim 4, wherein the sun tracking assembly comprises a sunlight sensor and a rotating shaft, the sunlight sensor is fixed on the rotating shaft, the high power optical lens is disposed on the sunlight sensor, the rotating shaft is disposed on the bracket, the sunlight sensor is configured to track an irradiation direction of the sunlight, and the rotating shaft is configured to drive the high power optical lens and the sunlight sensor to rotate along with the sun.

6. The light energy processing apparatus of claim 4, wherein the sun tracking assembly comprises a solar tracker on which the high power optical lens is disposed and a universal ball, the solar tracker being configured to track the sun; the universal rotating ball comprises a support and a ball body, the support is arranged on the support and comprises a groove, the ball body is clamped in the groove and can roll in the groove, the solar tracker is arranged on the ball body, and the ball body is used for driving the high-power optical lens and the solar tracker to follow the sun to rotate.

7. The optical energy processing apparatus of claim 1, wherein the control assembly comprises a central processing unit, a power module, and a driving circuit, the central processing unit being coupled to the power module and the driving circuit, the central processing unit being configured to control the transmission of the electrical energy to the mobile device.

8. The optical energy processing apparatus of claim 1, wherein the processing assembly further comprises a feeding device disposed on the moving device, the feeding device configured to feed the material into the mold; the charging device is further coupled with the control assembly, which is further configured to transmit the electrical energy to the charging device to power the charging device.

9. The light energy processing device as claimed in claim 8, wherein the moving means comprises a platform and a moving mechanism, the platform being disposed on the moving mechanism, the platform being adapted to carry the mold and the charging device; the moving mechanism is used for driving the platform to move in a two-dimensional direction.

10. The light energy processing device of claim 1, wherein said daylighting power-generating component comprises a plurality of photovoltaic power-generating panels, said plurality of photovoltaic power-generating panels being arranged in an array, a daylighting surface of each of said photovoltaic power-generating panels facing said sun; the preset shape includes at least one of a cuboid, a cube, a prism, a cylinder, and an irregular shape.

Images