CN211400967U - Target paper and target drone device - Google Patents

Abstract

The application provides a target paper and target drone device belongs to shooting articles for use technical field. The target paper comprises a base layer, a light reflection gain layer and an energy storage luminous layer. The reflection gain layer is positioned between the base layer and the energy storage luminous layer, and when the excitation light irradiates on the energy storage luminous layer, the energy storage luminous layer can emit excited light. The target drone device with the target paper also comprises a support frame, and the target paper is fixedly connected with the support frame. When the target drone device with the structure is used for shooting training at night, the target paper is not required to be irradiated by an external light source, the shooting environment is prevented from being limited and influenced by external light source equipment during shooting training at night, and the authenticity and effectiveness of the shooting training at night and the training effect of shooting are improved.

Description

Target paper and target drone device

Technical Field

The application relates to the technical field of shooting articles, in particular to target paper and a target drone device.

Background

Target paper and a target drone are important equipment for military training. At present, military night shooting is an important item for military night training, the existing night shooting training mainly adopts the mode that searchlights irradiate target paper and the like to indicate targets, and target shooting equipment used in the mode needs external light source equipment to irradiate, so that the shooting environment is limited and influenced by the external light source equipment and is inconsistent with the actual combat condition, the authenticity and effectiveness of the night shooting training are reduced, and the training effect of shooting is influenced.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a target paper and a target drone device to improve the problem that the shooting environment is limited and influenced by external light source equipment during shooting training at night.

In a first aspect, an embodiment of the present application provides a target paper, including a base layer, a light reflection gain layer, and an energy storage light emitting layer; the light reflection gain layer is positioned between the base layer and the energy storage luminous layer; when the excitation light irradiates on the energy storage luminescent layer, the energy storage luminescent layer can emit excited light.

In the technical scheme, the target paper comprises a base layer, a light reflection gain layer and an energy storage luminous layer. In actual use, the reflective gain layer can firmly bond the particles of the energy storage luminous layer, and can reflect and reuse spectra of some wave bands, so that the utilization rate of light energy is improved. When the light emitting layer is irradiated by the exciting light, the energy storage light emitting layer can absorb and store light energy and release the excited light. The energy storage and the light emitting effects of the target paper are achieved through the simple structure, the target paper can continuously emit light during shooting training at night, and the indication function of shooting targets is further achieved.

In addition, the target paper provided by the embodiment of the application also has the following additional technical characteristics:

further, the target paper also comprises a shielding layer; the shielding layer is positioned between the base layer and the light reflection gain layer.

In the above technical solution, the target paper further includes a shielding layer, and the shielding layer is located between the base layer and the reflection enhancement layer. In practical use, the shielding layer can obstruct the color of the base layer, improve the color contrast of the pattern and the base layer, reduce the influence of the color of the base layer on the light absorption of the light emitting layer, and further improve the light emitting effect of the target paper. In addition, the masking layer enhances the adhesion strength and aging resistance of the other layers to the base layer.

Further, the target paper also comprises a transparent protective layer; the energy storage luminous layer is positioned between the light reflection gain layer and the transparent protective layer.

In the above technical scheme, the target paper is further provided with a transparent protective layer, the energy storage luminescent layer is located between the reflection gain layer and the transparent protective layer, and the transparent protective layer plays a role in assisting in bonding and fixing particles of the energy storage luminescent layer. In addition, the transparent protective layer improves the scratch resistance of the target paper, and further improves the actual service life of the target paper.

Further, the surface of the transparent protective layer forms a concave-convex structure.

In the technical scheme, the surface of the transparent protective layer is of a concave-convex structure, so that the target paper has a hydrophobic effect, and the water resistance and the antifouling capacity of the target paper are further improved.

In a second aspect, an embodiment of the present application further provides a target drone device, including a support frame and the target paper; the target paper is fixedly connected to the support frame.

In above-mentioned technical scheme, the target drone device includes support frame and target paper, when carrying out the shooting training night, the target paper can continuously send after the light energy of absorption exciting light and is excited the light energy and be instructed to shooting the target, replaced the shining of external light source equipment, realize real no light shooting environment, the shooting environment receives the restriction and the influence of external light source equipment when having avoided the shooting training night, and then improved the authenticity and the validity of shooting training night and the training effect of shooting.

In addition, the drone aircraft device that this application embodiment provided still has following additional technical characterstic:

further, the target drone device also comprises a light source for providing excitation light for the energy storage luminescent layer.

In the technical scheme, the light source can provide exciting light for the energy storage luminescent layer, and the source of the exciting light is ensured during night shooting training, so that the problem that the energy storage luminescent layer cannot provide a light emitting function for target paper after light energy is released is avoided, and the use duration of the target paper is further shortened.

Further, the support frame comprises a base and a first bracket; the target paper is connected to the first bracket; the first support is rotatably arranged on the base and can rotate between a shooting position and an energy charging position relative to the base; when the first support is located at the energy charging position, the light source can provide exciting light for the energy storage luminous layer.

In above-mentioned technical scheme, first support can rotate between shooting position and the position of charging relative base to can drive the target paper and be close to the light source, make first support be located when charging the position, the light source can provide the exciting light for the energy storage luminescent layer, and then realize that the light source charges the energy storage luminescent layer. When needs carried out the shooting training, first support can rotate to the shooting position relative to the base, for the training personnel provides the shooting demand, through this kind of simple structure for the target paper realizes the shooting position through first support and fills the transform that can the position.

Further, the drone aircraft apparatus also includes a drive mechanism; the driving mechanism is used for driving the first support to rotate between the shooting position and the energy charging position relative to the base.

In the technical scheme, the driving mechanism can drive the first support to rotate between the shooting position and the energy charging position relative to the base. In the in-service use process, when stopping midway when the shooting training, actuating mechanism can drive first support and rotate to the position of can filling, and when the shooting training continued, actuating mechanism can drive first support and rotate to the shooting position, and then has realized filling the function of ability to the target paper is automatic, and the luminous effect of target paper has been guaranteed to this kind of structure, and the target paper is in the luminous state of filling the ability and accomplishing all the time when the shooting needs. In addition, the structure avoids the need of light energy supplement to the target paper by workers in shooting training, thereby saving manpower.

Further, the drone aircraft device also includes a trigger switch; the trigger switch is connected to the base and used for controlling the light source to be turned on or off; when the first bracket is located at the charging position, the first bracket triggers the trigger switch to turn on the light source.

In the technical scheme, the target drone device further comprises a trigger switch, and when the driving mechanism drives the first support to rotate to the energy charging position, the trigger switch can be triggered by the first support to turn on the light source, so that the light source emits exciting light to charge the energy storage light emitting layer. On the contrary, when the driving mechanism drives the first support to rotate away from the charging position, the first support is disconnected from the trigger of the trigger switch, so that the light source can be turned off. The structure avoids the situation that the light source is always in an open state when the target paper is in the shooting position, thereby causing the waste of energy. In addition, in the night shooting training, the exciting light emitted by the light source is prevented from influencing the shooting sight of the trainee.

Further, the drone aircraft apparatus also includes a second stand; the light source is connected to the second bracket; the second bracket is connected to the base.

In above-mentioned technical scheme, the light source passes through the second support connection on the base, and when target paper rotated to the position of can filling through the relative base of first support, target paper was in same position with the light source for the exciting light that the light source sent can accurately fill the energy to the energy storage luminescent layer and can, and then has reduced the loss of light energy.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

FIG. 1 is a schematic structural diagram of a drone aircraft device according to an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a target paper of the drone device according to an embodiment of the present application;

FIG. 3 is a schematic illustration of a target paper of a drone aircraft device according to some embodiments of the present application;

FIG. 4 is a schematic structural view of a target paper of a target drone device according to yet other embodiments of the present application.

Icon: 100-a drone device; 10-target paper; 11-a base layer; 12-a reflective gain layer; 13-an energy storing light emitting layer; 14-a shielding layer; 15-transparent protective layer; 20-a support frame; 21-a base; 22-a first bracket; 30-a light source; 40-a drive mechanism; 50-trigger switch; 60-second bracket.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, 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 some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. 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 application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the embodiments of the present application, it should be noted that the indication of orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, or the orientation or positional relationship which is usually placed when the product of the application is used, or the orientation or positional relationship which is usually understood by those skilled in the art, or the orientation or positional relationship which is usually placed when the product of the application is used, and is only for the convenience of describing the application and simplifying the description, but does not indicate or imply that the indicated device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the application. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

Examples

As shown in fig. 1, the embodiment of the present application provides a target drone device 100, which includes a target paper 10 and a support stand 20, wherein the target paper 10 is fixedly connected to the support stand 20.

When carrying out the night shooting training, target paper 10 can continuously send the excited light after absorbing the light energy of excited light, instructs shooting target, has replaced the shining of external light source equipment, realizes the dull shooting environment of real meaning, and the shooting environment receives the restriction and the influence of external light source equipment when having avoided the night shooting training, and then has improved the authenticity and the validity of night shooting training and the training effect of shooting.

In this embodiment, as shown in fig. 2, the target paper 10 includes a base layer 11, a reflection enhancing layer 12, and an energy storage luminescent layer 13. The light reflection enhancing layer 12 is located between the base layer 11 and the energy storage light emitting layer 13. When the excitation light is irradiated on the energy storage light emitting layer 13, the energy storage light emitting layer 13 can emit the excited light.

In practical use, the light reflection gain layer 12 can firmly bond the particles of the energy storage light emitting layer 13, and can reflect and reuse some band spectrums, thereby improving the utilization rate of light energy. When irradiated with the excitation light, the energy-storing light-emitting layer 13 can absorb and store light energy and release the excited light. The energy storage and the light emitting effects of the target paper 10 are realized through the simple structure, so that the target paper 10 can continuously emit light during night shooting training, and the indication function of shooting targets is further realized.

The base layer 11 plays a role of laying other layers, and the material of the base layer 11 can be a dark plastic plate, and can also be a paper plate, a foam plate or a metal plate.

Optionally, the reflection enhancement layer 12 is applied to the masking layer 14 by gravure printing. In other embodiments, the reflection enhancement layer 12 may be laid on the shielding layer 14 by other methods, for example, silk-screen printing, inkjet printing, etc.

Illustratively, the composition of the reflection enhancement layer 12 comprises 10% -20% of titanium dioxide coating, 10% -40% of aluminized hollow glass beads, 30% -70% of titanium white pigment, 30% -90% of high-gloss thermosetting resin, 0% -10% of coating auxiliary agent and 0.1% -6% of surface dielectric treatment agent, wherein the particle size of the beads is 0.5-400 μm.

It should be noted that the aluminized hollow glass beads used in the composition of the reflection enhancing layer 12 may also be hollow ceramic beads. The high light thermosetting resin used in the composition of the reflection enhancing layer 12 may also be a UV curable resin.

Optionally, the energy storage light emitting layer 13 is laid on the light reflection gain layer 12 by electrostatic adsorption. Before the light reflection gain layer 12 is laid on the shielding layer 14 and dried, the base layer 11 is placed on the electrostatic plate, and then the material of the energy storage luminescent layer 13 is blown onto the light reflection gain layer 12. The microbeads in the reflection gain layer 12 form an ordered structure through electrostatic induction before drying, and the reflection gain layer 12 contacts with the material of the blown energy storage luminescent layer 13, so that the material of the energy storage luminescent layer 13 is laid on the reflection gain layer 12 in an electrostatic adsorption mode. Due to the influence of electrostatic adsorption, part of the material of the energy storage luminescent layer 13 will infiltrate into the light reflection gain layer 12 and be wrapped by the micro-beads to form a plurality of luminescent reflectors, and the material of the energy storage luminescent layer 13 which is not adsorbed by the light reflection gain layer 12 will be blown away, and then collected and reused. And finally, the energy storage luminous layer 13 is subjected to ultraviolet curing and infrared drying in sequence, and the energy storage luminous layer 13 and the light reflection gain layer 12 are subjected to curing stabilization.

Illustratively, the energy-storing luminescent layer 13 comprises 10-90% of long afterglow luminescent powder, 0-30% of transparent resin and 0-10% of surface treatment auxiliary agent.

The light emitted by the long-afterglow luminescent powder can be various, such as purple light, yellow light, green light or other visible wavelengths. In this embodiment, the long afterglow luminescent powder is composed of rare earth ion mixed strontium aluminate series luminescent powder, and in other embodiments, the long afterglow luminescent powder may also be composed of rare earth ion mixed silicate series luminescent powder, sulfide luminescent powder, and the like.

Further, as shown in FIG. 1, the target drone device 100 also includes a light source 30 for providing excitation light to the energy storage luminescent layer 13.

When shooting training is carried out at night, the light source 30 can provide exciting light for the energy storage luminescent layer 13, and the source of the exciting light is ensured, so that the problem that the energy storage luminescent layer 13 cannot provide a light emitting function for the target paper 10 after light energy is released is avoided, and the use duration of the target paper 10 is further shortened.

The light source 30 is used to provide excitation light for the energy-storing light-emitting layer 13, so as to charge the energy-storing light-emitting layer 13. In this embodiment, the light source 30 is an LED lamp bead with a main peak and a peak wavelength of 280nm to 480nm, and provides excitation light for the energy storage light emitting layer 13. In other embodiments, the light source 30 may have other structures, for example, the light source 30 may be a xenon lamp or an ultraviolet fluorescent lamp with a main peak and peak wavelength of 280nm to 480 nm.

Illustratively, the light source 30 may be in the shape of a square strip or a circular disk.

Optionally, the support stand 20 includes a base 21 and a first support 22. The target 10 is connected to a first bracket 22, the first bracket 22 is rotatably disposed on the base 21, and the first bracket 22 can rotate between a shooting position and a charging position relative to the base 21. When the first support 22 is in the charging position, the light source 30 can provide excitation light for the energy storing light emitting layer 13.

In the practical use process, first support 22 can rotate between shooting position and the position of charging relative base 21 to can drive target paper 10 and be close to light source 30, make first support 22 be located the position of charging, light source 30 can provide the exciting light for energy storage luminescent layer 13, and then realize that light source 30 charges energy storage luminescent layer 13. When shooting training is needed, the first support 22 can rotate to the shooting position relative to the base 21, so that shooting requirements are provided for training personnel, and the target paper 10 can be changed between the shooting position and the charging position through the first support 22 through the simple structure.

It should be noted that the supporting frame 20 is not limited to this structure, for example, the supporting frame 20 is integrally a frame structure, the target paper 10 is connected to the frame structure, and the frame structure is fixedly connected to the ground or other fixed objects.

The drone device 100 may be driven by human power to rotate the first carriage 22 between the shooting position and the charging position relative to the base 21, or may be driven by other methods to rotate the first carriage 22 between the shooting position and the charging position relative to the base 21.

Illustratively, the drone device 100 also includes a drive mechanism 40, the drive mechanism 40 being configured to drive the first carriage 22 to rotate relative to the base 21 between a firing position and a charging position.

In actual use, the driving mechanism 40 can drive the first support 22 to rotate between the shooting position and the charging position relative to the base 21. When stopping midway when the shooting training, actuating mechanism 40 can drive first support 22 and rotate to the position of can filling, and when the shooting training continued, actuating mechanism 40 can drive first support 22 and rotate to the shooting position, and then realized the function of filling the ability to target paper 10 is automatic, and this kind of structure has guaranteed the luminous effect of target paper 10, and target paper 10 is in the luminous state of filling the ability completion all the time when the shooting needs. In addition, the structure avoids the need of light energy supplement to the target paper 10 by workers in shooting training, thereby saving manpower.

Wherein the drive mechanism 40 functions to drive the first support 22 to rotate relative to the base 21 between the firing position and the charging position. In this embodiment, the driving mechanism 40 is a motor, and a gear on the output end of the motor is engaged with a gear on the first support 22 to drive the first support 22 to rotate between the shooting position and the charging position relative to the base 21. In other embodiments, the structure of the driving mechanism 40 is not limited thereto, for example, the driving mechanism 40 is a hydraulic motor, and a gear on the output end of the hydraulic motor is engaged with a gear provided on the first support 22 to drive the first support 22 to rotate between the shooting position and the charging position relative to the base 21.

Further, the drone device 100 also includes a trigger switch 50. The trigger switch 50 is connected to the base 21, and the trigger switch 50 is used to control the light source 30 to be turned on or off. When the first bracket 22 is in the charged position, the trigger switch 50 can be triggered by the first bracket 22 to turn on the light source 30.

When the driving mechanism 40 drives the first support 22 to rotate to the charging position, the trigger switch 50 can be triggered by the first support 22 to turn on the light source 30, so that the light source 30 emits the excitation light to charge the energy storage light emitting layer 13. Conversely, when the driving mechanism 40 drives the first bracket 22 to rotate away from the charging position, the first bracket 22 is triggered off the trigger switch 50, so that the light source 30 can be turned off. This configuration avoids the light source 30 being constantly on when the backing paper 10 is in the firing position, which would result in wasted energy. In addition, in the night shooting training, the excitation light emitted from the light source 30 is prevented from affecting the shooting sight of the trainee.

Illustratively, the trigger switch 50 is a travel switch, and when the driving mechanism 40 drives the first bracket 22 to rotate to the charging position relative to the base 21, the first bracket 22 is in direct contact with the travel switch as an input signal, so that the travel switch turns on the light source 30. When the driving mechanism 40 drives the support 20 to rotate relative to the base 21 away from the charging position, the first support 22 is disconnected from the travel switch, which is used as an input signal, so that the travel switch turns off the light source 30. In other embodiments, the trigger switch 50 may have other structures, for example, the trigger switch 50 is an optical signal switch or a metal proximity switch.

It should be noted that the trigger switch 50 may also be connected to the light source 30, and when the driving mechanism 40 drives the first bracket 22 to rotate to the charging position relative to the base 21, the first bracket 22 or the target paper 10 will be triggered by the trigger switch 50 connected to the light source 30, so as to turn on the light source 30.

Optionally, the drone device 100 further includes a second bracket 60. The light source 30 is attached to the second bracket 60, and the second bracket 60 is attached to the base 21.

In practical use, the light source 30 is connected to the base 21 through the second support 60, and when the target paper 10 rotates to the energy charging position relative to the base 21 through the first support 22, the target paper 10 and the light source 30 are located at the same position, so that the excitation light emitted by the light source 30 can accurately charge the energy storage light emitting layer 13, and further the loss of light energy is reduced.

It should be noted that the target drone device 100 may not be provided with a second frame, and the light source 30 may be connected to the ground so that the light source 30 can provide excitation light to the target paper 10.

The target paper 10 includes a base layer 11, a reflection enhancing layer 12 and an energy storage luminescent layer 13. In some embodiments of the present application, as shown in fig. 3, the target paper 10 further includes a shielding layer 14, the shielding layer 14 being located between the base layer 11 and the reflection enhancing layer 12.

In the actual use process, the shielding layer 14 can block the color of the base layer 11, improve the color contrast of the pattern and the base layer 11, and reduce the influence of the color of the base layer 11 on the light absorption of the light emitting layer, thereby improving the light emitting effect of the target paper 10. In addition, the shielding layer 14 enhances the adhesion strength and aging resistance of the other layers to the base layer 11.

The shielding layer 14 serves to block the color of the base layer 11, improve the color contrast of the pattern with the base layer 11, and reduce the effect of the color of the base layer 11 on the light absorption of the light emitting layer. The color of the shielding layer 14 may be various, and in this embodiment, the shielding layer 14 is white. In other embodiments, the masking layer 14 may be other colors, such as light gray, light yellow, etc.

In this embodiment, the masking layer 14 is applied to the base layer 11 by gravure printing. In other embodiments, the masking layer 14 may be applied by other methods, for example, the masking layer 14 is applied on the substrate 11 by offset printing, silk-screen printing, inkjet printing, etc.

Illustratively, the shielding layer 14 comprises 30% -70% of rutile titanium dioxide, 20% -30% of titanium dioxide coated hollow glass beads, 5% -20% of zirconium powder beads, 1% -4% of organosilicon surfactant, 10% -40% of acrylic resin, 0% -5% of auxiliary agent and 5% -20% of organic solvent.

The acrylic resin used in the composition of the shielding layer 14 may be a urethane resin.

The target paper 10 includes a base layer 11, a shielding layer 14, a reflection enhancing layer 12 and an energy storage luminescent layer 13. In some embodiments of the present application, as shown in fig. 4, the target paper 10 further includes a transparent protective layer 15, and the energy storage and light emitting layer 13 is located between the light reflection and gain layer 12 and the transparent protective layer 15.

The target paper 10 is further provided with a transparent protective layer 15, the energy storage luminescent layer 13 is located between the reflection gain layer 12 and the transparent protective layer 15, and the transparent protective layer 15 plays a role in assisting in bonding and fixing particles of the energy storage luminescent layer 13. In addition, the transparent protective layer 15 improves the scratch resistance of the target paper 10, which in turn improves the practical life of the target paper 10.

The transparent protective layer 15 is laid on the energy storage luminescent layer 13 by gravure printing, or by spray printing, silk screen printing or inkjet printing.

Illustratively, the transparent protective layer 15 comprises 40% -80% of resin, 20% -30% of aluminized hollow reflective glass beads, 1% -4% of hydrophobic fumed silica and 1% -3% of an auxiliary agent.

The aluminized hollow reflective glass beads adopted in the composition of the transparent protective layer 15 can also be ceramic beads.

In this embodiment, in the process of drying the transparent protection layer 15 at a high temperature, the organic solvent in the shielding layer 14 is rapidly volatilized at a high temperature, so that the concave-convex structure is formed on the surface of the transparent protection layer 15.

In practical use, the surface of the transparent protective layer 15 is of a concave-convex structure, so that the target paper 10 has a hydrophobic effect, and the water resistance and the antifouling capacity of the target paper 10 are improved.

It should be noted that the shielding layer 14, the reflection enhancing layer 12, the energy storage luminescent layer 13 and the transparent protective layer 15 are sequentially laid on the base layer 11 from bottom to top, each layer is laid according to the outline of the anthropomorphic target map, and after the shielding layer 14, the reflection enhancing layer 12, the energy storage luminescent layer 13 and the transparent protective layer 15 are laid, the pattern of the anthropomorphic target map is formed on the target paper 10.

In practical use, the target paper 10 can continuously emit light after storing energy, and the shooting training personnel can carry out shooting training at night through the target paper 10. When the shooting is stopped in the middle of shooting, the driving mechanism 40 can drive the first bracket 22 to rotate to the charging position relative to the base 21, so as to drive the target paper 10 to be close to the light source 30. When the target paper 10 approaches the light source 30, the first bracket 22 triggers the trigger switch 50 connected to the base 21 to turn on the light source 30, and the light source 30 provides the exciting light to charge the target paper 10. When shooting training is needed, the driving mechanism 40 drives the first support 22 to rotate relative to the base 21 away from the charging position, so that the contact between the first support 22 and the trigger switch 50 is broken, the light source 30 is turned off, and the phenomenon that exciting light emitted by the light source 30 affects the shooting effect of training personnel and causes energy waste is avoided. When the driving mechanism 40 drives the first support 22 to rotate to the shooting position relative to the base 21, the training personnel can continue shooting training, so that a real lightless shooting environment is realized, the shooting environment is prevented from being limited and influenced by external light source equipment during shooting training at night, and the authenticity and effectiveness of the shooting training at night and the training effect of shooting are improved.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. The target paper is characterized by comprising a base layer, a light reflection gain layer and an energy storage luminous layer;

the light reflection gain layer is positioned between the base layer and the energy storage luminous layer;

when the excitation light irradiates on the energy storage luminescent layer, the energy storage luminescent layer can emit excited light.

2. The target paper of claim 1, further comprising a masking layer;

the shielding layer is positioned between the base layer and the light reflection gain layer.

3. The target paper of claim 2, further comprising a transparent protective layer;

the energy storage luminous layer is positioned between the light reflection gain layer and the transparent protective layer.

4. The target paper according to claim 3, wherein the surface of the transparent protective layer is formed with a textured structure.

5. A target drone device, characterized by comprising a support frame and a target paper according to any one of claims 1 to 4;

the target paper is connected to the support frame.

6. The target machine device of claim 5, further comprising a light source for providing excitation light to the energy storing luminescent layer.

7. The target drone assembly of claim 6, wherein the support bracket includes a base and a first bracket;

the target paper is connected to the first bracket;

the first support is rotatably arranged on the base and can rotate between a shooting position and an energy charging position relative to the base;

when the first support is located at the energy charging position, the light source can provide exciting light for the energy storage luminous layer.

8. The drone aircraft device of claim 7, further comprising a drive mechanism;

the driving mechanism is used for driving the first support to rotate between the shooting position and the energy charging position relative to the base.

9. The drone aircraft device of claim 8, further comprising a trigger switch;

the trigger switch is connected to the base and used for controlling the light source to be turned on or off;

when the first bracket is located at the charging position, the first bracket triggers the trigger switch to turn on the light source.

10. The drone aircraft device of any one of claims 7 to 9, further comprising a second stand;

the light source is connected to the second bracket;

the second bracket is connected to the base.

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