LASER TOY AND LASER GAME

Abstract

A laser toy comprises a base provided with a plurality of disassembly structures and a plurality of different types of functional modules. Each of the disassembly structures is configured to detachable connect one of the plurality of different types of functional modules. Each of the functional modules comprises a bracket and a functional part, the bracket is configured to detachable connect the disassembly structure, and the functional part is disposed on the bracket. The different types of functional modules includes a laser emitting module, a laser receiving module and a reflecting module. The functional part of the laser emitting module is a laser transmitter for emitting laser; the functional part of the laser receiving module is a laser receiver for receiving laser. The functional part of the reflecting module is a reflector for reflecting the laser emitted from the laser emitting module toward the laser receiving module.

Claims

1. A laser toy comprising: a base provided with a plurality of disassembly structures; a plurality of different types of functional modules, each of the disassembly structures is configured to detachable connect one of the plurality of different types of functional modules, wherein: each of the functional modules comprises a bracket and a functional part, the bracket is configured to detachable connect the disassembly structure, and the functional part is disposed on the bracket; the different types of functional modules includes a laser emitting module, a laser receiving module and a reflecting module; the functional part of the laser emitting module is a laser transmitter for emitting laser; the functional part of the laser receiving module is a laser receiver for receiving laser; the functional part of the reflecting module is a reflector for reflecting the laser emitted from the laser emitting module toward the laser receiving module.

2. The laser toy of claim 1, wherein: the reflector includes a lateral mirror or a longitudinal mirror, wherein the lateral mirror is parallel to the vertical direction, the longitudinal mirror is at an angle to the vertical direction.

3. The laser toy of claim 1, wherein: the functional module further comprises a laser blocking module, the functional part of the laser blocking module is a laser blocker for preventing the laser from passing through the laser blocker.

4. The laser toy of claim 1, wherein: the bracket comprises a supporting frame and a disassembly base; an accommodating cavity is defined in the supporting frame, and a transmissive port is formed on at least one side thereof; the disassembly base is detachably connected to the supporting frame, the disassembly base is configured to detachably connect with one of the disassembly structures, and the accommodating cavity is configured to set the functional part.

5. The laser toy of claim 4, wherein: the disassembly base is provided with a positioning bulge for positioning with at least one of the disassembly structures.

6. The laser toy of claim 5, wherein: the disassembly base is provided with a snap-on bulge for snap-fitting the supporting frame;

7. The laser toy of claim 6, wherein: a first clamp cavity is formed between the positioning bulge and the snap-on bulge for clamping the supporting frame of one bracket.

8. The laser toy of claim 5, wherein: an abutting bulge is arranged on a side of the disassembly base away from the supporting frame; each of the disassembly structures is a disassembly slot; when an end of the disassembly base is accommodated in the disassembly slot, the abutting bulge abuts against the inner wall of the disassembly slot.

9. The laser toy of claim 8, wherein: a second clamp cavity is formed between the positioning bulge and the abutting bulge to form for clamping the supporting frame of another bracket.

10. The laser toy of claim 9, wherein: the disassembly base is provided with a yielding gap located on one side of the abutting bulge.

11. The laser toy of claim 4, wherein: the supporting frame comprises a first frame and a second frame; the first frame is detachably connected to the second frame for forming the accommodating cavity.

12. The laser toy of claim 4, wherein: the supporting frame is provided with a stacking port at the end away from the disassembly base; when at least two supporting frames are stacked, one supporting frame is detachably connected to the disassembly base of the other supporting frames by the stacking port.

13. The laser toy of claim 12, wherein: the supporting frame comprises a fixing port; the fixing port is arranged at one end of the supporting frame away from the stacking port, the disassembly base is detachably connected to the fixing port.

14. The laser toy of claim 13, wherein: the fixing port and the stacking port are the same shape; the stacking port and the fixing port are symmetrically arranged at both ends of the support frame, so that the disassembly base is configured to be mounted either on the fixing port or the stacking port.

15. The laser toy of claim 4, wherein: the disassembly base is a first magnet and the disassembly structure is provided with a second magnet; the first magnet is magnetically attracted with the second magnet.

16. A laser game comprising: providing a laser receiving module and a laser emitting module in two different regions of a base; calculating a laser transmission path, a laser reflecting area is define as the turning position in the laser transmission path; setting a reflecting module in the laser reflecting area to adjust laser to be transmitted along the laser transmission path; turning on the laser emitting module and observing the laser arrives the laser.

17. The laser game of claim 16, wherein the step of calculating a laser transmission path comprises: determining a first sub-path outgoing from the laser emitting module and determining a second sub-path incident to the laser receiving module; if the first sub-path and the second sub-path intersect, the area where the first sub-path and the second sub-path intersect is the laser reflecting area; if the first sub-path and the second sub-path do not intersect, determining a third sub-path connecting the first sub-path and the second sub-path, and the third sub-path is at least partially perpendicular to the first sub-path or the second sub-path, then the area in which the first sub-path and the third sub-path intersect is one of the laser reflecting area, and the area in which the second sub-path and the third sub-path intersect is the other one of the laser reflecting area.

18. The laser game of claim 16, wherein the step of providing a laser receiving module and a laser emitting module in two different regions of a base comprises: providing a laser blocking module in the base; the step of calculating a laser transmission path further comprises: calculating the laser transmission path, and if the laser transmission path passes through the laser blocking module, calculating an avoidance sub-path to replace the portion of the laser transmission path that passes through the laser blocking module, the avoidance sub-path is a path around the laser blocking module for preventing the laser from blocking by the laser blocking module.

19. The laser game of claim 16, wherein the step of providing a laser receiving module and a laser emitting module in two different regions of a base comprises: providing a functional module at the bottom of the laser transmitter and/or the laser receiver for adjusting the height of the laser transmitter and/or the laser receiver.

20. The laser game of claim 19, wherein the step of calculating the laser transmission path comprises: determining whether the laser receiving module and the laser emitting module are at the same height; if the laser receiving module and the laser emitting module are located at the same height, adjusting the height of the reflecting module on the first laser path for setting the reflecting module at the same height of the laser receiving module; if the laser receiving module and the laser emitting module are not located at the same height, providing two longitudinal mirrors stacked for adjusting the height of the laser emitted by the laser transmitter module and the height of the laser received by the laser receiver module.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] Many aspects of the disclosure can be better understood with reference to the following drawings. The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of the disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.

[0007] FIG. 1 is a schematic diagram of a laser toy of the present disclosure.

[0008] FIG. 2 is a schematic diagram of a functional module of the present disclosure, wherein the functional module comprises a reflection module having a longitudinal mirror.

[0009] FIG. 3 is a schematic diagram of a first application scenario of the laser toy of the present disclosure.

[0010] FIG. 4 is a schematic diagram of a second application scenario of the laser toy of the present disclosure.

[0011] FIG. 5 is a schematic diagram of a third application scenario of the laser toy of the present disclosure.

[0012] FIG. 6 is a schematic diagram of a fourth application scenario of the laser toy of the present disclosure.

[0013] FIG. 7 is an exploded diagram of a supporting frame and a disassembly base of the laser toy.

[0014] FIG. 8 is a schematic view of two brackets connected of the present disclosure.

[0015] FIG. 9 is an exploded diagram of a first frame and a second frame disassembled.

[0016] FIG. 10 is a local enlarged diagram of area A in FIG. 1.

[0017] FIG. 11 is a cross-sectional diagram of FIG. 8.

[0018] FIG. 12 is an exploded diagram of a disassembly base provided with a first magnet and the disassembly structure provide with a second magnet.

DETAILED DESCRIPTION

[0019] It will be appreciated that for simplicity and clarity of illustration, where appropriate, reference numerals have been repeated among the different FIG. s to indicate corresponding or analogous elements. In addition, numerous specific details are set forth in order to provide a thorough understanding of the embodiments described herein. However, it will be understood by those of ordinary skill in the art that the embodiments described herein can be practiced without these specific details. In other instances, methods, procedures, and components have not been described in detail so as not to obscure the related relevant feature being described. Also, the description is not to be considered as limiting the scope of the embodiments described herein. The drawings are not necessarily to scale and the proportions of certain parts have been exaggerated to better illustrate details and features of the present disclosure.

[0020] The present disclosure, including the accompanying drawings, is illustrated by way of examples and not by way of limitation. Several definitions that apply throughout this disclosure will now be presented. It should be noted that references to an or one embodiment in this disclosure are not necessarily to the same embodiment, and such references mean at least one.

[0021] The term coupled is defined as connected, whether directly or indirectly through intervening components, and is not necessarily limited to physical connections. The connection can be such that the objects are permanently connected or releasably connected. The term comprising means including, but not necessarily limited to; it specifically indicates open-ended inclusion or membership in a so-described combination, group, series, and the like.

[0022] Without a given definition otherwise, all terms used have the same meaning as commonly understood by those skilled in the art. The terms used herein in the description of the present disclosure are for the purpose of describing specific embodiments only, and are not intended to limit the present disclosure.

[0023] As shown in FIG. 1, a laser toy 1 includes a base 10 and a plurality of different types of functional modules 20.

[0024] The base 10 is provided with a plurality of disassembly structures 11. Each of the disassembly structures 11 is configured to detachable connect a functional module 20.

[0025] A plurality of amounting areas are defined on the base 10, each area is provided with one of the plurality of disassembly structure 11. Optionally, each of the plurality of disassembly structure 11 is a disassembly slot 112. In some embodiments, the plurality of amounting areas on the base 10 are matrix distributed, and the plurality of disassembly structures 11 are matrix distributed on the base 10. In some other embodiments, the manner in which the plurality of amounting areas distributed on the base 10 may be adjusted according to actual requirements.

[0026] Understandably, the plurality of different types of functional modules 20 is able to be amounted on the plurality of amounting areas on the base 10. The position of each of the plurality of different types of functional modules 20 is able to be adjusted. The plurality of different types of functional modules 20 may include at least one type of the functional module 20 or more than two types of the functional modules 20.

[0027] Different types of the functional modules 20 in the present disclosure are configured to achieve different functional. The different types of the functional modules 20 include at least three different types: a laser emitting module 21, a laser receiving module 22, and a reflecting module 23. The laser emitting module 21 is used for emitting the laser, the laser receiving module 22 for receiving the laser, and the reflecting module 23 for reflecting the laser. When the laser emitting module 21, the laser receiving module 22 and the reflecting module 23 are all amounted on the base 10, the laser emitting module 21, the laser receiving module 22 and reflecting module 23 are amounted in different amounting areas.

[0028] As shown in FIGS. 1 and 2, each type of the function modules 20 has a bracket 60 and a functional portion 50 in which the bracket 60 is detachable connected to the disassembly structure 11 and the functional portion 50 is disposed to the bracket 60. The functional portion 50 of one function module 20 is configured to realize the function corresponding to the functional module 20, of which different types of the function modules 20 have different types of the functional portions 50. All types of the functional modules 20 have the same type of the bracket 60 to simplify the producing process.

[0029] In some embodiments, the functional portion 50 of the laser emitting module 21 is a laser transmitter 51, and the laser transmitter 51 is configured to emit a laser. The functional portion 50 of the laser receiving module 22 is a laser receiver 52, which is configured to receive the laser.

[0030] The functional portion 50 of the reflecting module 23 is a reflector 53. When the laser emitted by the laser emitting module 21 reaches the reflector 53, the reflector 53 is able to reflect the laser to enable the laser to reach the laser receiving module 22. It is understood that the reflector 53 refers to a structure with a laser reflecting function, which can be a mirror or a semi-lens. When the reflector 53 is a semi-lens, the laser reached the semi-lens is able to be divided into two laser paths. One of the laser paths travels along the extension direction of the laser, and the other one travels along the direction of the semi-lens reflection.

[0031] In some embodiments, the reflector 53 includes a lateral mirror 2310 or a longitudinal mirror 2320. When the base 10 is placed on the horizontal plane and the function module 20 is mounted on the base 10, the lateral mirror 2310 is arranged parallel to the vertical direction, the longitudinal mirror 2320 is arranged at an angle to the vertical direction.

[0032] As shown in FIGS. 1 and 2, in some embodiments, the bracket 60 comprises a supporting frame 30 and a disassembly base 40. An accommodating cavity 31 is formed in the supporting frame 30. The accommodating cavity is configured to set the functional portion 50. The side aspect of the supporting frame 30 forms a transmissive port 32 for the laser to pass through. The disassembly base 40 is connected to the supporting frame 30 and the disassembly base 40 is detachably connected with the disassembly structure 11. In some embodiments, the supporting frame 30 of the same type of the function modules 20 has the disassembly base 40.

[0033] As shown in FIGS. 2 and 7, in some embodiments, the profile of the supporting frame 30 is square, and the supporting frame 30 is a plastic frame so that the supporting frame 30 has a certain deformation capacity based on being able to provide support strength. The supporting frame 30 is internally hollow to form the accommodating cavity 31, and the transmissive port 32 is formed on the peripheral side of the supporting frame 30.

[0034] In some embodiments, one end of the supporting frame 30 is provided with a fixed port 33, the fixed port 33 is communicating to the accommodating cavity 31, and the disassembly base 40 is detachable connected to the supporting frame 30 at the location of the fixing port 33. It is understandable that the removable connection between the supporting frame 30 and the disassembly base 40 is convenient for repairing and replacing the disassembly base 40.

[0035] As shown in FIGS. 2,7, and 8, in some embodiments, a stacking port 34 is provided at one end of the supporting frame 30 away from the fixing port 33, and the stacking port 34 is connected to the accommodating cavity 31. In the case of a plurality of the support frames 30 stacked on top of each other, the support frames 30 of the plurality of the support frames 30 is able to be detachable connected to the disassembly base 40 of the other support frames 30 through the stacking port 34.

[0036] It is understood that when the plurality of the functional modules 20 are stacked, the plurality of the support frames 30 are stacked in the vertical direction, and the disassembly base 40 of the upper supporting frame 30 may be installed in the stacking port 34 of the supporting frame 30 located below to ensure the stacking stability of the plurality of the functional modules 20 and prevent plurality of the functional modules 20 from dumping.

[0037] In some embodiments, the stacking port 34 of the supporting frame 30 is provided with chamfered surfaces at the corners of the stacking port 34, the chamfered surfaces being used to cooperate with other disassembly bases 40 to improve the installation efficiency of the positioning structure.

[0038] In some embodiments, the stacking port 34 of the supporting frame 30 is symmetrically disposed with the fixing port 33. Exemplarily, the upper and lower ends of the supporting frame 30 are mirror symmetrical with a horizontal plane passing through the geometric center of the supporting frame 30 so that the structure of the stacking port 34 is symmetrical with the structure of the fixing port 33. Both the stacking port 34 and the fixing port 33 may be fitted with a disassembly base 40 so that both the stacking port 34 and the fixing port 33 may be interchangeable.

[0039] For example, when the fixing port 33 of the supporting frame 30 is provided facing downward, the disassembly base 40 corresponding to the supporting frame 30 may be mounted at the fixing port 33, and the disassembly bases 40 of the other stacking supporting frames 30 may be mounted at the stacking ports 34. When the stacking port 34 of the supporting frame 30 is provided facing downward, the stacking ports 34 may be regarded as the fixing ports 33, the fixing ports 33 may be regarded as the stacking ports 34, and the disassembly bases corresponding to the supporting frame 30 may be mounted to the stacking port 34, and the disassembly bases 40 of the other stacked supporting frames 30 may be mounted to the fixing port 33. In this way, the requirement of the mounting position of the disassembly bases 40 on the supporting frames 30 is reduced, and the efficiency of the assembly of the functional module 20 is improved.

[0040] As shown in FIGS. 1 and 7, in some embodiments, the inner side of the supporting frame 30 is recessed inwardly to form a positioning slot 35. The positioning slot 35 is configured to adapt to position the functional portion 50.

[0041] As shown in FIGS. 2 and 9, in some embodiments, a plurality of mounting slots 301 are provided inside the supporting frame 30, and the plurality of mounting slots 301 are used for positioning the reflector 53. Specifically, the plurality of mounting slots 301 include transverse mounting slots 36 and longitudinal mounting slots 37.

[0042] Wherein the inner walls of the sides of the supporting frame 30 are recessed inwardly to form transverse mounting slots 36 for positioning the lateral mirror 2310. The inner walls of the ends of the supporting frame 30 are recessed inwardly to form longitudinal mounting slots 37 for positioning the longitudinal mirror 2320.

[0043] In some embodiments, the supporting frame 30 includes a first frame 38 and a second frame 39, the first frame 38 and the second frame 39 are enclosed to form the accommodating cavity 31. The first frame 38 and the second frame 39 are secured in a manner including, but not limited to, snap-fit, bolt-fit, adhesive, and the like.

[0044] When the first frame 38 and the second frame 39 are spliced and fixed, the first frame 38 and the second frame 39 are enclosed to form the accommodating cavity 31, and both the first frame 38 and the second frame 39 are able to cooperate to limit the functional part 50.

[0045] It can be understood that when assembling the supporting frame 30, the disassembly base 40 and the functional part 50, the disassembly base 40 and the functional part 50 can be placed between the first frame 38 and the second frame 39, and then the first frame 38 and the second frame 39 can be fixed to fix the disassembly base 40 and the functional part 50 inside the supporting frame 30, which can improve the efficiency of assembly.

[0046] In some embodiments, the first frame 38 and the second frame 39 are centrosymmetric along a vertical plane passing through the geometric center of the supporting frame 30. It is understood that the first frame 38 and the second frame 39 have the same structure for simplifying the producing process.

[0047] As shown in FIGS. 7 and 8, in some embodiments, the disassembly base 40 has an overall ring shape and the cross-sectional shape of the disassembly base 40 is rectangular. The disassembly base 40 may be made of a plastic material to allow the disassembly base 40 to have a certain deformation capacity on top of being able to provide support strength.

[0048] The disassembly base 40 has a first end and a second end, wherein the first end of the disassembly base 40 is coupled to the supporting frame 30, wherein the dimensions of the first end of the disassembly base 40 are adapted to the dimensions of the fixing ports 33 so that the first end of the disassembly base 40 can be inserted into the fixing ports 33 of the corresponding supporting frame 30; and wherein the dimensions of the second end of the disassembly base 40 are adapted to the dimensions of the stacking ports 34 so that the disassembly base 40 second end can be inserted into the stacking port 34 of the other supporting frame 30.

[0049] In some embodiments, a snap-on bulge 41 is provided on a side of the first end of the disassembly base 40, and the snap-on bulge 41 is used to snap-fitting the supporting frame 30. In some embodiments, the snap-on bulge 41 is formed on an outer projection of the first end of the disassembly base 40, and a snap-on bulge 41 is formed on each side of the disassembly base 40. the first end of the disassembly base 40 is housed within the fixing port 33 of the supporting frame 30, and the snap-on bulge 41 is retained in the supporting frame 30 from the the inner side of the supporting frame 30 against the supporting frame 30 to securely connect the first end of the disassembly base 40 to the supporting frame 30.

[0050] When the disassembly base 40 needs to be assembled in the supporting frame 30, the first end of the disassembly base 40 can be inserted into the fixing port 33 of the supporting frame 30 so as to allow the snap-on bulge 41 to enter the supporting frame 30 from the inner side of the supporting frame 30 to be abutted against the supporting frame 30, which is simple and convenient to install and improves the efficiency of assembly. Moreover, the disassembly base 40 and the supporting frame 30 are detachably connected by the snap-in structure, which is convenient for disassembling and replacing the disassembly base 40.

[0051] As shown in FIGS. 7 and 10, in some embodiments, the disassembly base 40 is provided with a positioning bulges 42 on the sides, and the positioning bulges 42 are used to cooperate with the disassembly structure 11 for positioning. The disassembly structure 11 is a disassembly slot 112 provided in the base 10. Optionally, the disassembly base 40 is formed with the positioning bulge 42 protruding from the outer side of the disassembly base 40, and the positioning bulge 42 is formed on each side of the disassembly base 40. The side wall of the disassembly slot 112 is provided with the positioning slot 111 corresponding to the positioning bulge 42.

[0052] When the disassembly base 40 is mounted on the disassembly structure 11, the disassembly base 40 is positioned by means of the positioning slot 111 cooperating with the positioning bulge 42 to improve the mounting solidity of the disassembly base 40.

[0053] In some embodiments, the side of the second end of the disassembly base 40 is provided with abutting bulges 43. Optionally, an outer projection of the second end of the disassembly base 40 is formed with the abutting bulges 43, and the disassembly base 40 is formed with the abutting bulges 43 at each of the corners.

[0054] When the second end of the disassembly base 40 is housed in the disassembly structure 11, the abutting bulge 43 is abutted against a side wall of the disassembly bore 112 to secure the disassembly base 40 to the disassembly structure 11.

[0055] When the disassembly base 40 is required to be mounted to the disassembly structure 11, the second end of the disassembly base 40 may be inserted into the disassembly structure 11 so that the respective abutting bulge 43 rests against the sidewall of the disassembly bore 112, securing the disassembly base 40 by friction.

[0056] As shown in FIGS. 7 and 11, in the case where the second end of the disassembly base 40 is mounted in the stacking port 34 of the other supporting frame 30, the second end of the disassembly base 40 is housed within the stacking port 34 of the supporting frame 30. The abutting bulge 43 is abutted against the supporting frame 30 from an inner side of the supporting frame 30 to securely connect the second end of the disassembly base 40 to the supporting frame 30.

[0057] When it is desired to mount the disassembly base 40 to the other supporting frame 30, the second end of the disassembly base 40 may be inserted into the stacking port 34 of the supporting frame 30. the respective abutting bulge 43 is then brought to rest against the chamfered surface of the stacking port 34. Eventually, each abutting bulge 43 is brought into the inner side of the supporting frame 30 to rest against the supporting frame 30.

[0058] As shown in FIG. 10, it will be appreciated that the disassembly base 40 may be mounted to the disassembly structure 11 by means of the abutting bulge 43, or may be mounted to other support brackets by means of the abutting bulge 43.

[0059] In some embodiments, the disassembly base 40 is provided with a yielding gap 44, the yielding gap 44 being located on a side of the abutting bulge 43. It will be appreciated that the yielding gap 44 may increase the shape capacity of the portion of the disassembly base 40 proximate to the abutting bulge 43, reducing the risk of damage to the disassembly base 40 during installation and removal.

[0060] In some embodiments, the positioning bulge 42 is provided in the middle of the disassembly base 40, and a distance is left between the positioning bulge 42 and the first end of the disassembly base 40 to allow a spacing between the positioning bulge 42 and the snap-on bulge 41 to form a first clamp cavity 45. And, a distance is also left between the positioning bulge 42 and the second end of the disassembly base 40 to allow a spacing between the positioning bulge 42 and the abutting bulge 43 forming a second clamp cavity 46.

[0061] Wherein the first clamping cavity 45 is used to clamp the corresponding supporting frame 30, in the case where the first end of the disassembly base 40 is connected to the corresponding supporting frame 30, an edge portion of the fixing port 33 of the supporting frame 30 is clamped in the first clamping cavity 45 to enable the positioning bulge 42 to cooperate with the snap-on bulge 41 in fixing the supporting frame 30, thereby improving the connection stability between the first end of the disassembly base 40 and the corresponding supporting frame 30. thereby improving the stability of the connection between the first end of the disassembly seat 40 and the corresponding support frame 30.

[0062] In the case where the second end of the disassembly base 40 is attached to the other supporting frame 30, the edge portion of the stacking port 34 of the supporting frame 30 is clamped in the second clamp cavity 46 to allow the positioning bulge 42 to cooperate with the abutting bulge 43 in securing the supporting frame 30, thereby improving the stability of the connection between the second end of the disassembly base 40 and the other supporting frame 30.

[0063] As shown in FIG. 10, it is to be understood that the disassembly base 40 may play a positioning role by positioning bulge 42 cooperating with the disassembly structure 11, and may also be fixed to different supporting frames 30 by positioning bulge 42 cooperating with abutting bulge 43 or snap-on bulge 41, simplifying the fixing structure and facilitating disassembly.

[0064] In some embodiments, the disassembly base 40 is a first magnet 81 and the disassembly structure 11 on the base is provided with a second magnet 82. The first magnet 81 is magnetically attracted with the second magnet 82 so that the functional module 20 is attracted to the base. A third magnet 83 is provided at the stacking port 34, and the first magnet 81 of one functional module 20 is magnetically attracted with the third magnet 83 of the other functional module, causing the two functional modules 20 to be connected along the third direction Z.

[0065] As shown in FIGS. 1 and 7, in some embodiments, the laser transmitter 51 of the laser emitting module 21 may be a laser transmitter, the laser transmitter 51 being fixed within the corresponding supporting frame 30, and the transmitting end of the laser transmitter 51 being exposed on a side of the corresponding supporting frame 30.

[0066] The shape of the laser transmitter 51 is adapted to the positioning slot 35. When the laser transmitter 51 is housed in the accommodating cavity 31, the circumferential edge portion of the laser transmitter 51 can be held against the slot wall of the positioning slot 35 to ensure the mounting stability of the laser transmitter 51.

[0067] In some embodiments, the laser transmitter 51 is further provided with an on/off button, the on/off button being exposed at the top of the corresponding supporting frame 30. The laser transmitter 51 is able to be simply activated or deactivated through the switch button.

[0068] In some embodiments, the laser receiver 52 of the laser receiving module 22 may be a laser sensor, the laser receiver 52 being secured within a corresponding supporting frame 30, and the target surface end of the laser receiver 52 being exposed on a side of the corresponding supporting frame 30.

[0069] The shape of the laser receiver 52 is adapted to the positioning slot 35. When the laser receiver 52 is housed in the accommodating cavity 31, the circumferential edge portion of the laser receiver 52 is able to resist the slot wall of the positioning slot 35 to ensure the mounting stability of the laser receiver 52.

[0070] In some embodiments, the laser receiver 52 is further provided with an indicator 521, the indicator 521 being exposed on a side of the corresponding supporting frame 30. When the laser receiver 52 receives the laser, the indicator 521 may be illuminated.

[0071] In some embodiments, the shape of the laser blocker 54 of the laser blocking module 24 is adapted to the positioning slot 35, and the laser blocker 54 is able to fill the internal space corresponding to the supporting frame 30 to achieve the effect of laser blocking. When the light-shielding laser blocker 54 is housed in the accommodating cavity 31, a circumferential edge portion of the light-shielding laser blocker 54 is able to resist the slot wall of the positioning slot 35 to ensure the mounting stability of the light-shielding laser blocker 54.

[0072] As shown in FIGS. 2 and 9, in some embodiments, the shape of the reflecting module 23's reflector 53 is adapted to the mounting slots 301. Two ends of the reflector 53 are respectively snapped to a plurality of mounting slots 301 of the corresponding supporting frame 30 to realize the fixation of the reflector 53. The two ends of the lateral mirror 2310 are respectively snap-fitted into the transverse mounting slots 36 of the corresponding supporting frame 30. The two ends of the longitudinal mirror 2320 are respectively snapped into the longitudinal mounting slot 37 of the corresponding supporting frame 30.

[0073] As shown in FIG. 1, in this embodiment, the functional module 20 further comprises a transmissive module 25, and the laser can be transmitted through the functional part 50 of the transmissive module 25. It will be appreciated that, in the case of a stacked installation, the transmissive module 25 can be provided at the bottom of the other functional module 20 for configuring the other functional module 20 as a second layer functional module or a third layer functional module. For example, the transmissive module 25 may be used in conjunction with a reflecting module 23 having a lateral mirror 2310 installed in the second layer module to reflect laser located in the second layer.

[0074] In some embodiments, the supporting frame 30 of the transmissive module 25 is internally vacant to allow the accommodating cavity 31 itself to form a functional part 50. the functional part 50 not only has the property of transmitting light, but also allows for mounting space for the disassembly base 40 of the other functional modules 20.

[0075] As shown in FIGS. 1 and 2, it is noteworthy that in this embodiment, each functional module 20 may adopt the same bracket 60, so that the same bracket 60 may be suitable for mounting different functional parts 50, and the standardization of the bracket 60 is realized, so that the production cost can be reduced and the production efficiency can be improved. In other embodiments, each functional module 20 may adopt a different supporting frame 30 or disassembly base 40, for example, the laser emitting module may directly use the housing of the laser transmitter 51 as the supporting frame 30, and fix the disassembly base 40 to the bottom of the housing, etc., and the present disclosure is not limited thereto.

[0076] The laser toy 1 is capable of being applied to games on top of being able to visualize optical phenomena. For example, the laser toy 1 may be accompanied by a challenge card, which records the types and positions of the pieces to be placed on the board. The player needs to place each functional module 20 on the corresponding position of the base 10 in accordance with the type and position of the pieces according to the challenge card, and to enable an effective laser propagation path to be formed between each functional module 20.

[0077] The present disclosure also includes a laser game. This laser game includes steps: [0078] S11, providing a laser receiving module and a laser emitting module in two different regions of a base. [0079] S12, calculating a laser transmission path, a laser reflecting area is define as the turning position in the laser transmission path. [0080] S13, setting a reflecting module in the laser reflecting area to adjust laser to be transmitted along the laser transmission path. [0081] S14, turning on the laser emitting module and observing the laser arrives the laser. [0082] the step of calculating the laser transmission path 70 comprises: [0083] S121, determining a first sub-path outgoing from the laser emitting module and determining a second sub-path incident to the laser receiving module;

[0084] If the first sub-path and the second sub-path intersect, the area where the first sub-path and the second sub-path intersect is the laser reflecting area;

[0085] If the first sub-path and the second sub-path do not intersect, determining a third sub-path connecting the first sub-path and the second sub-path, and the third sub-path is at least partially perpendicular to the first sub-path or the second sub-path, then the area in which the first sub-path and the third sub-path intersect is one of the laser reflecting area, and the area in which the second sub-path and the third sub-path intersect is the other one of the laser reflecting area.

[0086] In the step of providing the laser receiving module and the laser emitting module in two different regions of the base, the laser game further comprises the step of: [0087] S111, providing a laser blocking module in the base.

[0088] If the base is provided with the laser blocking module 24, the step of calculating the laser transmission path 70 is also included in the step of: [0089] S122, calculating the laser transmission path, and if the laser transmission path passes through the laser blocking module, calculating an avoidance sub-path to replace the portion of the laser transmission path that passes through the laser blocking module, the avoidance sub-path is a path around the laser blocking module for preventing the laser from blocking by the laser blocking module.

[0090] In the step of providing the laser receiving module and the laser emitting module in two different regions of the base, the laser game further comprises the step of: [0091] S112, providing a functional module at the bottom of the laser transmitter and/or the laser receiver for adjusting the height of the laser transmitter and/or the laser receiver.

[0092] If there are at least one functional module at the bottom of the laser transmitter and/or the laser receiver, this is also included in the step of calculating the laser transmission path: [0093] S123, determining whether the laser receiving module and the laser emitting module are at the same height in the third direction Z; [0094] If the laser transmitter and the laser receiver are located at the same height in the third direction Z, all reflecting modules on the first laser path are adjusted in the third direction Z by means of other functional modules; [0095] if the laser receiving module and the laser emitting module are located at the same height in the third direction Z, adjusting the height of the reflecting module on the first laser path for setting the reflecting module at the same height in the third direction Z of the laser receiving module.

[0096] FIGS. 1 and 3 show a first application scenario of such a laser toy 1.

[0097] In a first application scenario, the laser toy 1 is located in a space formed by a first direction X, a second direction Y and a third direction Z. The laser toy 1 is located in the space formed by a first direction X, a second direction Y and a third direction Z. It is divided into twenty five squares in the first direction X direction and the second direction Y direction. When the base 10 is placed flat on a horizontal surface, the first direction X and the second direction Y are parallel to the horizontal surface, and the third direction Z is a vertical direction.

[0098] The laser emitting module 21 is positioned at A (X1, Y5, Z1), and the laser emitting module 21 emits laser along the first direction X positive direction. The position of the laser receiving module 22 is B (X5, Y1, Z1), and the laser receiving module 22 receives laser along the second direction Y negative direction. [0099] determining a first sub-path 71 outgoing from the laser transmitter and determining a second sub-path 72 incident to the laser receiver;

[0100] The first sub-path 71 and the second sub-path 72 intersect, and the area where the first sub-path 71 and the second sub-path 72 intersect is the laser reflecting area 77. the laser reflecting area 77 is obtained as (X5, Y5, Z1). The position of the reflecting module 23 is C (X5, Y5, Z1). The reflecting module 23 has a lateral mirror 2310, and the reflecting module 23 reflects the laser between the first direction X direction and the second direction Y direction.

[0101] In this way, the laser emitting module 21 emits laser that can reach the reflecting module 23, which reflects the laser so that the laser can finally reach the laser receiving module 22.

[0102] In this embodiment, the number of reflecting modules 23 may also be greater than or equal to 2, and the plurality of reflecting modules 23 may cooperate with each other to reflect the laser.

[0103] FIG. 4 shows a second application scenario of such a laser toy 1.

[0104] In a second application scenario, the laser toy 1 is located in a space formed by the first direction X, the second direction Y and the third direction Z. The laser toy 1 is located in a space formed by the first direction X, the second direction Y and the third direction Z. It is divided into twenty five squares in the first direction X direction and the second direction Y direction.

[0105] The position of the laser emitting module 21 is A (X1, Y5, Z1), and the laser emitting module 21 emits laser along the first direction X positive direction. The position of the laser receiving module 22 is B (X1, Y1, Z1), and the laser receiving module 22 receives laser along the first direction X negative direction. [0106] determining a first sub-path 71 outgoing from the laser transmitter and determining a second sub-path 72 incident to the laser receiver;

[0107] The first sub-path 71 and the second sub-path 72 do not intersect, a third sub-path 73 connecting the first sub-path 71 and the second sub-path 72 is computed, the third sub-path 73 is perpendicular to the first sub-path 71 or the second sub-path 73, the area where the first sub-path 71 and the third sub-path 73 intersect is a laser reflecting area 77, and the area where the second sub-path 72 and the third sub-path 73 intersect is also a laser reflecting region 77.

[0108] Both laser reflecting areas 77 are provided with reflecting modules 23, and the number of reflecting modules 23 is 2. The reflecting modules 23 have lateral mirrors 2310, and the reflecting modules 23 reflect laser between the first direction X direction and the second direction Y direction. The two reflecting modules 23 comprise a reflecting module 23a and a reflecting module 23b, wherein the position of the reflecting module 23a is Ca (X5, Y5, Z1) and the position of the reflecting module 23b is Cb (X5, Y1, Z1).

[0109] In this way, the laser emitting module 21 emits laser that can reach the reflecting module 23a, and the laser is reflected through the reflecting module 23a and the reflecting module 23b in turn so that the laser can finally reach the laser receiving module 22.

[0110] It is understood that by mounting the laser emitting module 21 in different areas, the laser emitting direction and the laser emitting position of the laser emitting module 21 can be changed. By installing the laser receiving module 22 in different regions, the laser receiving direction and the laser receiving position of the laser receiving module 22 can be changed. By installing the laser reflecting module 23 in different areas, the laser propagation path can be changed. After adjusting the position of the laser emitting module 21 and the position of the laser receiving module 22, a corresponding laser route can be developed so that the laser emitted by the laser emitting module 21 is directed into the laser structure module 22. At least one reflecting module 23 is mounted on the base 10 to cause the laser to propagate along the formulated laser route. In use, parents can place the laser emitting module 21 and the laser receiving module 22 in different areas of the base 10. A child can think for himself in order to formulate the laser route and install the reflecting module 23 on the base 10 to cause the laser to propagate along the laser route formulated by the child.

[0111] As shown in FIG. 1, in some embodiments, the functional module 20 further comprises a laser blocking module 24, the functional part 50 of the laser blocking module 24 being a laser blocker 54 for preventing the laser from passing through the laser blocker. It is to be understood that the laser blocking module 24 may block the laser from passing through and increase the interference factor of the laser propagation path in the laser toy to improve the fun of the laser toy.

[0112] FIG. 5 shows a third application scenario of such laser toy 1.

[0113] In a third application scenario, the laser toy 1 is located in a space formed by the first direction X, the second direction Y and the third direction Z. The laser toy 1 is located in a space formed by the first direction X, the second direction Y and the third direction Z. It is divided into twenty five squares in the first direction X direction and the second direction Y direction.

[0114] The position of the laser emitting module 21 is A (X1, Y5, Z1), and the laser emitting module 21 emits laser along the first direction X positive direction. The position of the laser receiving module 22 is B (X1, Y1, Z1), and the laser receiving module 22 receives laser along the first direction X negative direction.

[0115] The position of the laser blocking module 24 is D (X5, Y3, Z1).

[0116] The laser transmission path 70 is calculated as shown in FIG. 4, but the laser transmission path 70 passes through the laser blocking module 24. the avoidance subpath 78 is calculated to replace the portion of the laser transmission path 70 that passes through the laser blocking module 24, and the avoidance subpath 78 is set around the laser blocking module 24 to avoid the laser blocking module 24.

[0117] The number of laser reflecting areas 77 in the laser transmission path 70 with the avoidance sub-path 78 is four, and the number of reflecting modules 23 is four. The reflecting modules 23 have lateral mirrors 2310, and the reflecting modules 23 reflect laser between the first direction X direction and the second direction Y direction. The four reflecting modules 23 include a reflecting module 23a, a reflecting module 23b, a reflecting module 23c, and a reflecting module 23d, wherein the position of the reflecting module 23a is Ca (X5, Y5, Z1), the position of the reflecting module 23b is Cb (X5, Y4, Z1), the position of the reflecting module 23c is Cc (X3, Y4, Z1), and the position of the reflecting module 23d is Cd (X3, Y1, Z1).

[0118] In this way, the laser emitting module 21 emits a laser that can reach the reflecting module 23a, and the laser is reflected through the reflecting module 23a, the reflecting module 23b, the reflecting module 23c, and the reflecting module 23d in turn, so that the laser can finally reach the laser receiving module 22.

[0119] In some embodiments, at least two functional modules 20 are mounted stacked along the third direction Z to support diverse laser propagation path designs. A bracket 60 of one functional module 20 is attached to the top of a bracket 60 of another functional module 20 in the third direction Z. The functional module 20 mounted directly on the base 10 is named the first layer module, the functional module 20 located above the first layer module is named the second layer functional module, and the functional module 20 located above the second layer module is named the third layer functional module. Understandably, as the number of functional modules 20 located at the bottom increases, the functional module 20 located at the top may also be a fourth layer module or otherwise. Among other things, the longitudinal mirror 2320 can change the propagation direction of the laser, and the laser propagating parallel to the horizontal plane propagates along the third direction Z after being reflected by the longitudinal mirror 2320.

[0120] FIG. 6 shows a fourth application scenario of such laser toy 1.

[0121] In the fourth application scenario, the laser toy 1 is located in the space formed by the first direction X, the second direction Y and the third direction Z. The laser toy 1 is located in the space formed by the first direction X, the second direction Y and the third direction Z. The base 10 is the same as the base 10 in the third application scenario, divided into twenty five squares in the first direction X direction and the second direction Y direction.

[0122] The laser emitting module 21 is positioned at A (X1, Y1, Z1) and the laser emitting module 21 emits laser along the first direction X positive direction.

[0123] The laser receiving module 22 is positioned at B (X1, Y1, Z3), and the laser receiving module 22 receives laser along the first direction X positive direction. The laser receiving module 22 is stack-mounted on the base 10 by two functional modules 20, which may be a laser blocking module 24 or a transmissive module 25.

[0124] The laser transmitter 21 and the laser receiver 22 are not located at the same height in the third direction Z. Two longitudinal mirrors 2320 stacked in the third direction Z are provided.

[0125] Specifically, the number of reflecting modules 23 is 2. The reflecting modules 23 have longitudinal mirrors 2320, and the reflecting modules 23 reflect the laser between the first direction X direction and the third direction Z direction. The two reflecting modules 23 comprise a reflecting module 23a and a reflecting module 23b, wherein the position of the reflecting module 23a is Ca (X3, Y1, Z1) and the position of the reflecting module 23b is Cb (X3, Y1, Z3).

[0126] The transmissive module 25 is positioned at E (X3, Y1, Z2). The reflecting module 23a is mounted on the base 10, the transmissive module 25 is stack mounted on the reflecting module 23a, and the reflecting module 23b is stack mounted on the transmissive module 25.

[0127] In this way, the laser emitting module 21 emits laser that can reach the reflecting module 23a, and the laser passes through the transmissive module 25 and is reflected by the reflecting module 23a and the reflecting module 23b in turn, so that the laser can finally reach the laser receiving module 22.

[0128] The embodiments shown and described above are only examples. Even though numerous characteristics and advantages of the present technology have been set forth in the foregoing description, together with details of the structure and function of the present disclosure, the disclosure is illustrative only, and changes may be made in the detail, including in matters of shape, size and arrangement of the parts within the principles of the present disclosure up to, and including, the full extent established by the broad general meaning of the terms used in the claims.