CN115155074A - Modeling system, building block system and using method thereof - Google Patents

Abstract

The invention provides a modeling system, a building block system and a using method thereof, wherein the modeling system comprises: a building block piece (100), a movable piece (200), a wire body (300) and an attachment piece (400); at least a portion of the wire body (300) is supported by the building block (100); the movable member (200) is detachably attached to the attachment member (400), and the movable member (200) is connected to the wire body (300). The invention combines the movable piece (200), the line body (300) and the building block piece (100), thereby enriching the playing method and the scene simulation of the building block; can respectively simulate moving objects such as aircrafts and the like and flight tracks thereof, and the movable piece (200) can shake after being touched by a user in a suspension state; allowing the user to freely design and plan the path of the linear body (300).

Description

Modeling system, building block system and using method thereof

Technical Field

The invention relates to the field of building blocks, in particular to a modeling system, a building block system and a using method of the building block system.

Background

The building block system is capable of simulating a variety of scenarios, such as beach scenarios, jungle scenarios, rocket launch scenarios, and the like. However, it is difficult to enrich the elements to be simulated by only relying on the conventional male and female head building blocks. Such as scenes of moving objects, e.g., flying football, racing cars, aircraft, etc., the prior art fails to provide a user experience of simulating a motion trajectory and moving objects.

Disclosure of Invention

In view of the shortcomings of the prior art, it is an object of the present invention to provide a molding system and a building block system and a method of using the same.

According to the invention, there is provided 1 a building block system, comprising: building block piece 100, movable piece 200, wire body 300, attachment piece 400;

at least a portion of the wire body 300 is supported by the building block 100;

the movable member 200 is detachably attached to the attachment member 400, and the movable member 200 is connected to the wire body 300.

Therefore, the fixed shape of the wire body 300 can not be separated from the movable piece 200, and the position and the posture of the movable piece 200 can not be separated from the wire body 300, and the two parts complement each other.

Preferably, the posture and/or position of the movable member 200 when attached to the attachment member 400 is affected by a pulling force of the wire body 300 on the movable member 200.

Preferably, when the movable element 200 is attached to the attachment element 400, a pulling force is applied to one end of the wire body 300 connected to the movable element 200;

alternatively, when the movable element 200 is attached to the attachment member 400, a supporting force is applied to a position where the wire body 300 contacts the movable element 200.

Preferably, any one of the following connection structures is adopted between the wire body 300 and the movable piece 200:

one end of the wire body 300 is fixedly connected with the movable piece 200;

one end of the wire body 300 is tied to the movable member 200;

one end of the wire body 300 has a wire head, which is confined in the inner cavity of the movable member 200;

the movable member 200 is strung on the wire body 300.

Preferably, the attachment member 400 is attached to the movable member 200 in a magnetic attraction manner or a magnetic suspension manner.

Thus, the range in which the posture of the movable member 200 can be adjusted is greatly increased.

Preferably, the attachment member 400 has a building block splicing structure;

the attachment member 400 is spliced with the block member 100 by the block splicing structure; alternatively, the attachment member 400 may be attached to the same floor block 500 as the building block 100.

Preferably, the block-splicing structure of the attachment member 400 comprises a male head and/or a female head; the building block 100 comprises a granular building block having a male and/or female head.

Thus, allowing a user to place the attachment member 400 in a number of different positions, the attachment position of the movable member 200 can be selected in a variety of ways.

Preferably, the wire body 300 extends through at least a portion of the building block 100 in contact therewith; alternatively, the wire body 300 may be wrapped around at least a portion of the building block 100 that is in contact.

Preferably, the angle formed by the wire body 300 passing through or around the building block 100 is acute.

In the extending direction of the wire body 300, the continuous plurality of break angles are all acute angles.

Thereby, the tension of the wire body 300 is improved.

Preferably, the number of turns of the wire body 300 is greater than or equal to one; the building blocks 100 in contact with the wire body 300 are spliced with other building blocks 100.

Preferably, in size, the through hole of the building block 100 penetrated by the wire body 300 and/or the clamping groove bypassed by the wire body 300 do not allow the movable member 200 to pass through.

Preferably, the length of the wire body 300 is fixed; or at least a portion of the wire body 300 is made of an elastic material.

Preferably, the end of the wire body 300 not connected to the movable member 200 is fixed or limited to the building block member 100.

Preferably, any one of the following connection structures is adopted between the end of the wire body 300 not connected with the movable piece 200 and the building block piece 100:

the end of the wire body 300, which is not connected with the movable piece 200, is fixedly connected with the building block piece 100;

the end of the wire body 300 not connected to the movable member 200 is tied to the building block member 100;

the end of the wire body 300 not connected to the movable member 200 has a wire head that is confined to one side of the through hole of the building block 100.

Preferably, the movable member 200 is suspended from the attachment member 400.

Preferably, the device also comprises an electric device;

when the movable member 200 is attached to the attachment member 400 in a contact manner, the power supply circuit of the electric device is turned on.

Preferably, the wire body 300 is a conducting wire, and when the movable member 200 is attached to the attachment member 400 in a contact manner, the conducting wire is electrically connected to the attachment member 400 through the movable member 200;

or, when the movable member 200 is attached to the attachment member 400 in a contact manner, the movable member 200 triggers a trigger switch on the attachment member 400, wherein the trigger switch controls on/off of the power supply loop of the consumer device.

The modeling system provided by the invention comprises a matching seat and the building block system arranged on the matching seat;

or the building block system comprises a shell and the building block system arranged in the shell.

According to the method for using the building block system, a part of the building blocks 100 is firstly strung on the line body 300, and then the part of the building blocks 100 is spliced to another part of the building blocks 100.

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

1. the invention combines the movable part 200, the line body 300 and the building block part 100, thereby enriching the playing method and the scene simulation of the building block.

2. According to the invention, moving objects such as aircrafts and the like and flight tracks thereof can be simulated respectively through the movable piece 200 and the wire body 300, and the movable piece 200 can shake after being touched by a user in a suspension state.

3. The present invention allows the user to freely design and plan the path of the linear body 300.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic view of the overall structure of the building block system provided by the invention.

Fig. 2 is a schematic diagram comparing the position and posture of the movable element under different pulling forces.

Fig. 3 is a schematic view of a line body path.

Figure 4 is a schematic view of another path of the wire body.

Fig. 5 is a schematic view of the movable element being biased in a different direction with respect to the wire of fig. 1.

The figures show that:

building block 100

Movable piece 200

Wire body 300

Attachment member 400

Floor block 500

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the invention, but are not intended to limit the invention in any way. It should be noted that it would be obvious to those skilled in the art that various changes and modifications can be made without departing from the spirit of the invention. All falling within the scope of the present invention.

As shown in fig. 1, according to the present invention, there is provided a building block system comprising: building block piece 100, movable piece 200, wire body 300, attachment piece 400; the building block 100 is a particle building block with male and female heads; the position of the mover 200 is determined by the attachment 400, and the posture of the mover 200 is determined by the wire body 300, that is, the resultant force of the adhesion force applied from the attachment 400 to the mover 200 and the tensile force applied from the wire body 300 to the mover 200 maintains the position and posture of the mover 200. The wire body 300 may be one or more.

At least a portion of the wire body 300 is supported by the building block 100; the wire body 300 is a flexible body whose shape is maintained by the support of the building block 100. In a preferred embodiment, all parts of the wire body 300 are supported by the building blocks 100, wherein different positions of the wire body 300 are supported by different building blocks 100, and the part between two adjacent supported points along the extension direction of the wire body 300 is understood to be supported to maintain the shape of a straight line segment.

The movable member 200 is detachably attached to the attachment member 400, and the movable member 200 is connected to the wire body 300. The movable member 200 does not need tools to allow a user to mount or detach the movable member 200 from the attachment member 400, and when the movable member 200 is attached to the attachment member 400 and the wire body 300 does not apply a pulling force to the movable member 200, the movable member 200 can rotate and/or translate relative to the attachment member 400. For example, the housing of the movable member 200 is made of plastic, and the magnet is disposed therein, and for example, the movable member 200 is made of a metal material such as iron.

As shown in fig. 2, the posture and/or position of the movable member 200 when attached to the attachment member 400 is affected by the pulling force of the wire body 300 on the movable member 200. When the movable member 200 is subjected to a small pulling force F1, the movable member 200 is attracted to the central position of the attachment member 400 by a magnetic attraction manner; when the movable member 200 is subjected to a large pulling force F2, the movable member 200 is magnetically attracted to a position offset from the center of the attachment member 400. Further, the pulling force F1 and the pulling force F2 are different in direction, so that the attitude angle of the movable member 200 with respect to the attachment member 400 is different. Further, due to the combined action of the adhesion force, such as the magnetic attraction force, and the pulling force applied by the adhesion member 400 to the movable member 200, a part of the adhesion force is cancelled by the pulling force to allow the movable member 200 to float in the air. Or the adhesive force offsets the gravity force to suspend the movable element 200, and the magnetic attraction force offsets the gravity force of the movable element 200 and the tensile force of the wire body 300 to suspend the movable element. The attachment member 400 may suspend the movable member 200 in the air by means of magnetic levitation, for example, magnetic force generated by a coil in the attachment member 400 may form magnetic levitation force, and may be considered as one of adhesion forces, that is, the adhesion force may not only be an attraction force, but also may be a repulsion force, as long as the movable member 200 can be held near the attachment member 400. For example, by comparing fig. 1 and 5, the wire body 300 applies a tensile force to the movable member from different directions, and the wire body 300 forms different directions of the applied force by splicing the blocks 100 at different positions.

More specifically, since the movable member 200 and the attachment member 400 are detachably connected, the mutual force between the two is smaller than the force of the user of the building block system, so that the user can still slightly shake the movable member 200 even under the combined action of the attachment force and the pulling force. It is natural that the movable member 200 may be slightly shaken by the user when it is in the floating state.

When the movable element 200 is attached to the attachment element 400, a pulling force is applied to one end of the wire body 300 connected to the movable element 200; alternatively, when the movable element 200 is attached to the attachment element 400, a supporting force is applied to a position where the wire body 300 contacts the movable element 200, for example, when the movable element 200 is strung on the wire body 300. The movable element 200 contributes to maintaining the wire body 300 in a tensioned state regardless of the pulling force or the supporting force.

The wire body 300 and the movable member 200 adopt any one of the following connection structures: one end of the wire body 300 is fixedly connected to the movable member 200, for example, the left and right halves of the movable member 200 hold the wire body 300; one end of the wire body 300 is tied to the movable member 200; one end of the wire body 300 has a thread end, which is confined in the inner cavity of the movable member 200; the movable member 200 is strung on the wire body 300.

The attachment member 400 is attached to the movable member 200 in a magnetic attraction manner or a magnetic suspension manner. The number of the attaching members 400 may be plural so that the movable member 200 can be attached at an attaching position. The attachment member 400 has a block splicing structure; the attachment member 400 is spliced with the block member 100 by the block splicing structure; alternatively, the attachment member 400 may be attached to the same floor block 500 as the building block 100. If the length of the wire body 300 is fixed, the position between the movable member 200 and the building block 100 can be adjusted by splicing the attachment member 400 and the building block 100 in a proper relative position, so that the wire body 300 is not loosened in tension. The building block splicing structure of the attachment member 400 includes a male head and/or a female head; the building block 100 comprises a granular building block having a male and/or female head.

The wire body 300 penetrates through at least one part of the building block piece 100 contacted with the wire body; alternatively, the wire body 300 may be wrapped around at least a portion of the building block 100 that is in contact. As shown in FIG. 3, the line body 300 has an acute break angle formed by passing through or around the building block 100. In the extending direction of the wire body 300, the continuous plurality of break angles are all acute angles.

In a preferred example, the number of turns of said passing of said wire body 300 is greater than or equal to one; the building blocks 100 in contact with the wire 300 are spliced to other building blocks 100. When a user pulls the movable member 200, the movable member 200 drives the wire body 300, and then the wire body 300 can pull and separate the coiled building block 100 from other building blocks, so as to realize a new building block playing method, for example, the coiled building block 100 is a building block with the appearance of an explosion point of a spacecraft, the movable member 200 is a spacecraft shuttle, and the wire body 300 is a flight track of the spacecraft shuttle, so that the building block playing method can simulate the sequential explosion of the explosion point on the flight track of the spacecraft shuttle and the separation of the spacecraft. Similarly, in another preferred embodiment, the through hole of the building block 100 penetrated by the wire body 300 and/or the clamping groove bypassed by the wire body 300 are not sized to allow the movable member 200 to pass through. Thus, the movable member 200 can be taught by pulling the wire body 300, so that the movable member 200 pulls down the building block 100 that cannot pass through.

The length of the wire body 300 is fixed; or at least a portion of the wire body 300 is made of an elastic material. The end of the wire body 300 not connected with the movable member 200 is fixed or limited to the building block member 100. The end of the wire body 300 which is not connected with the movable piece 200 and the building block piece 100 adopt any one of the following connection structures: the end of the wire body 300, which is not connected with the movable piece 200, is fixedly connected with the building block piece 100, for example, the building block piece is clamped between a spliced male head and a spliced female head; the end of the wire body 300 not connected to the movable member 200 is tied to the building block member 100; the end of the wire body 300 not connected to the movable member 200 has a thread end restricted to one side of the through hole of the building block 100.

More specifically, referring to fig. 3 and 4, by splicing the block piece 100 to a different position on the floor block 500, the user can change the path of the wire 300. The linear body 300 is used to simulate the motion trajectory of the aircraft simulated by the movable member 200, and the building block 100 simulates the explosive-like structure after the aircraft passes through.

In a preferred embodiment, the wire body 300 includes a conductive wire, and when the movable member 200 is attached to the attachment member 400 in a contact manner, the conductive wire is electrically connected to the attachment member 400 through the movable member 200, and the attachment member 400 is electrically connected to the electric device to conduct a power supply circuit of the electric device. Further, one end of the wire, which is not connected with the movable member 200, is connected with an electric device, that is, when the movable member 200 is attached to the attachment member 400 in a contact manner, the wire, the movable member 200, the attachment member 400, the power supply and the electric device form a communicated loop. The wire body 300 itself may be a wire. The electric device can be a light-emitting source such as an LED or an acoustic-optic device such as a buzzer. Wherein the light emitting source may be located in a transparent or translucent building block 100. In a modification, when the movable member 200 is attached to the attachment member 400 in a contact manner, the movable member 200 triggers a trigger switch on the attachment member 400, wherein the trigger switch controls the on/off of the power supply circuit.

The invention also provides a modeling system which comprises the matching seat and the building block system arranged on the matching seat.

The invention also provides a modeling system which comprises a shell and the building block system arranged in the shell.

The invention also provides a method for using the building block system, firstly, a part of building blocks 100 are strung on the line body 300, and then the part of building blocks 100 are spliced to another part of building blocks 100.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and therefore, are not to be construed as limiting the present application.

The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the invention. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.

Claims (20)

1. A building block system, comprising: a building block piece (100), a movable piece (200), a wire body (300) and an attachment piece (400);

at least a portion of the wire body (300) is supported by the building block (100);

the movable member (200) is detachably attached to the attachment member (400), and the movable member (200) is connected to the wire body (300).

2. The building block system according to claim 1, characterized in that the attitude and/or position of the movable member (200) when attached to the attachment member (400) is affected by the pulling force of the wire body (300) on the movable member (200).

3. The building block system according to claim 2, characterized in that when said movable member (200) is attached to said attachment member (400), a pulling force is applied to the end of said wire body (300) connected to said movable member (200);

or, when the movable element (200) is attached to the attachment element (400), a supporting force is applied to a position where the wire body (300) contacts the movable element (200).

4. The building block system according to claim 1, characterized in that any one of the following connection structures is adopted between said wire body (300) and said movable member (200):

one end of the wire body (300) is fixedly connected with the movable piece (200);

one end of the wire body (300) is tied to the movable piece (200);

one end of the wire body (300) has a wire head which is limited in the inner cavity of the movable piece (200);

the movable piece (200) is strung on the wire body (300).

5. The building block system according to claim 1, characterized in that the attachment between the attachment member (400) and the movable member (200) is performed magnetically or magnetically.

6. The building block system according to claim 1, wherein the attachment member (400) has a building block splicing structure;

the attachment piece (400) is spliced with the building block piece (100) through the building block splicing structure; alternatively, the attachment member (400) and the building block member (100) are spliced to the same floor block (500).

7. The building block system according to claim 6, characterized in that the building block splicing structure of the attachment member (400) comprises a male and/or a female head; the building block (100) comprises a particle building block with a male head and/or a female head.

8. The building block system according to claim 1, characterized in that said wire body (300) penetrates through at least a portion of the block elements (100) in contact therewith; alternatively, the wire body (300) is passed around at least a portion of the building block (100) in contact therewith.

9. The building block system according to claim 8, wherein a break angle formed by the line body (300) passing through or around the building block piece (100) is an acute angle.

10. The building block system according to claim 9, characterized in that along the extension direction of said line body (300), a plurality of said break angles in succession are all acute angles.

11. The building block system according to claim 8, characterized in that said number of turns of the wire body (300) is greater than or equal to one turn; the building block pieces (100) contacted with the wire body (300) are spliced with other building block pieces (100).

12. The building block system according to claim 8, characterized in that, dimensionally, the through-holes of the building blocks (100) through which the wire body (300) passes and/or the snap-in grooves by which the wire body (300) passes do not allow the passage of the movable member (200).

13. The building block system according to claim 1, characterized in that the length of the wire body (300) is fixed; or at least one part of the wire body (300) is made of elastic material.

14. The building block system according to claim 1, characterized in that the end of the wire body (300) not connected to the movable member (200) is fixed or restrained to the building block member (100).

15. The building block system according to claim 14, characterized in that the end of the wire body (300) not connected with the movable member (200) and the building block member (100) adopt any one of the following connection structures:

the end part of the wire body (300), which is not connected with the movable piece (200), is fixedly connected with the building block piece (100);

the end of the wire body (300) which is not connected with the movable piece (200) is tied to the building block piece (100);

the end of the wire body (300) not connected with the movable piece (200) is provided with a wire head, and the wire head is limited on one side of the through hole of the building block piece (100).

16. The building block system according to claim 1, wherein the movable member (200) is suspended from the attachment member (400).

17. The building block system of claim 1, further comprising an electrical device;

when the movable member (200) is attached to the attachment member (400) in a contact manner, a power supply circuit of the electric device is turned on.

18. The building block system according to claim 17, wherein the wire body (300) is a wire which is electrically connected to the attachment member (400) through the movable member (200) when the movable member (200) is attached in a contact manner to the attachment member (400);

or when the movable piece (200) is attached to the attachment piece (400) in a contact mode, the movable piece (200) triggers a trigger switch on the attachment piece (400), wherein the trigger switch controls the on-off of the power supply loop of the electrical appliance.

19. A molding system, comprising a counter, the building block system of any one of claims 1 to 18 arranged on the counter;

alternatively, a building block system comprising a housing, a building block system as claimed in any one of claims 1 to 18 provided in the housing.

20. A method of use of a building block system according to any one of claims 1-18, c h a r a c t e r i z e d in that a part of the building blocks (100) is first strung on a string (300) and then said part of the building blocks (100) is spliced to another part of the building blocks (100).

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