CN113975828B - Touch interactive building block system - Google Patents

Abstract

The invention provides a contact interaction building block system which comprises a command building block (100) matched with particles, and a touch switch (201) of the controlled building block (200) triggered by a protruding part (101) of the command building block (100) at least under one relative rotation azimuth angle A when the command building block (100) and the controlled building block (200) are in a splicing state. According to the invention, the instruction building block (100) sends an instruction to the controlled building block (200) in a mechanical triggering manner, so that the volume and cost of the building block system are reduced, and the correspondence and identification relationship between the instruction building block and the controlled building block is solved. A user can adjust the relative rotation azimuth angle between the instruction building block (100) and the controlled building block (200) through rotation action, and different input instructions can be switched; without detaching the command block (100) from the controlled block (200) to switch input commands. The invention does not influence the splicing mode of the original particle building blocks.

Description

Building block system with contact interaction

Technical Field

The present invention relates to the field of building blocks, and in particular to a touch interactive building block system.

Background

Patent document CN104383697A provides an electronic building block and an electronic building block set, which at least includes: the sensing module is used for sending and receiving wireless signals; the control module is used for controlling the sensing module to send the wireless signals and decoding control instructions contained in the received wireless signals; and the output module is used for carrying out visual display or sound output according to the specific content of the control instruction obtained by decoding of the control module. The electronic building blocks and the electronic building block set link wireless signals (such as infrared signals, bluetooth signals and the like) with light display changes and sound output through wireless communication sensors, output modules and microcontrollers.

In the prior art, instructions are transmitted among building blocks through wireless signals, and the building blocks at the instruction transmitting ends must contain wireless communication modules, so that the size and the cost of the building blocks are increased.

Disclosure of Invention

In view of the shortcomings of the prior art, it is an object of the present invention to provide a touch interactive construction system.

According to the invention, a touch interactive building block system is provided, comprising: the instruction block 100 and the controlled block 200;

adaptive particle building blocks are arranged between the instruction building block 100 and the controlled building block 200;

a protruding part 101 is arranged on the particle splicing surface 300 of the instruction building block 100;

a touch switch 201 is arranged on the particle splicing surface 300 of the controlled building block 200;

when the instruction block 100 and the controlled block 200 are in a splicing state, at least under one relative rotation orientation angle A, the protrusion part 101 of the instruction block 100 triggers the touch switch 201 of the controlled block 200;

preferably, the controlled block 200 comprises a circuit, wherein the circuit collects the trigger information of the touch switch 201 and obtains the instruction according to the trigger information.

Preferably, the number of the touch switches 201 is multiple, and the command is a coded command.

Preferably, the projection 101 of the command block 100 extends circumferentially in a ring-shaped configuration;

the number of the protruding parts 101 of the instruction building block 100 is one, and the number of the touch switches 201 of the controlled building block 200 is one or more, wherein a plurality of touch switches 201 are distributed at intervals in the radial direction; or alternatively

The number of the protruding parts 101 of the instruction block 100 is multiple, and the number of the touch switches 201 of the controlled block 200 is multiple and is greater than or equal to the number of the protruding parts 101, wherein the touch switches 201 are distributed at intervals in the radial direction.

Preferably, a plurality of annular-structure projections 101 are nested one within the other.

Preferably, when the command block 100 is connected to the controlled block 200, the protrusion 101 of the command block 100 avoids the touch switch 201 of the controlled block 200 at least at another relative rotation orientation angle B.

Preferably, when the instruction block 100 is connected to the controlled block 200, at least at a further relative rotation angle C, the protrusion 101 of the instruction block 100 also triggers the touch switch 201 of the controlled block 200;

different touch switches 201 exist between the touch switches 201 which are respectively triggered under the relative rotation azimuth angle A and the relative rotation azimuth angle C.

Preferably, the same touch switches 201 exist between the touch switches 201 which are respectively triggered under the relative rotation azimuth angle a and the relative rotation azimuth angle C.

Preferably, the projection 101 of the command block 100 is in the shape of a dot or a strip;

the number of the protruding parts 101 of the instruction building block 100 is one, and the number of the touch switches 201 of the controlled building block 200 is one or more, wherein a plurality of touch switches 201 are distributed at intervals in the circumferential direction and/or the radial direction; or

The number of the protruding parts 101 of the instruction building block 100 is multiple, and the number of the touch switches 201 of the controlled building block 200 is multiple and is greater than or equal to the number of the protruding parts 101, wherein the multiple touch switches 201 are distributed at intervals in the circumferential direction and/or the radial direction.

Preferably, a protruding part arrangement indication message and/or a protruding part orientation indication message is/are provided on the instruction block 100;

the projection type indication information indicating the distribution type of the projections 101;

the projection direction indicating information indicates the distribution direction of the projections 101.

Preferably, the controlled building block 200 is provided with touch switch type indication information and/or touch switch orientation indication information;

the touch switch type indication information is used for indicating the distribution type of the touch switch 201;

the touch switch orientation indication information is used for indicating the distribution orientation of the touch switches 201.

Preferably, a plurality of projection type indication information is provided on the instruction block 100, wherein the plurality of projection type indication information are respectively used for indicating distribution types of different sets of projections 101.

Preferably, when the instruction block 100 and the controlled block 200 are in a splicing state, a gap exists between the particle splicing surface 300 of the instruction block 100 and the particle splicing surface 300 of the controlled block 200 to avoid triggering the touch switch 201.

Preferably, the height of the protrusion 101 is smaller than the height of the gap and larger than the distance between the top end and the particle splicing surface 300 of the instruction brick 100 when the touch switch 201 is not triggered.

Preferably, the particle building blocks adopt round particles; when the instruction building block (100) and the controlled building block (200) are in a splicing state, allowing a user to circumferentially rotate and adjust the relative rotation azimuth angle between the instruction building block (100) and the controlled building block (200), so that:

the convex part (101) and the touch switch (201) which are triggered by mutual contact change to be separated from each other; or alternatively

The mutually separated convex parts (101) and the touch switch (201) are changed to be mutually contacted and triggered.

Preferably, when the user rotates the adjustment block in the circumferential direction to adjust the relative rotational orientation angle between the command block 100 and the controlled block 200:

the protruding part 101 of the instruction building block 100 moves along the circumferential direction along with the rotation, and different touch switches 201 on the controlled building block 200 can be triggered; and/or

The touch switch 201 of the controlled toy block 200 moves in the circumferential direction along with the rotation, and can be triggered by different protrusions 101 on the command toy block 100.

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

1. according to the invention, the instruction block 100 sends an instruction to the controlled block 200 in a mechanical triggering mode, so that the volume and the cost of the block system are reduced.

2. A user can switch different input instructions by adjusting the relative rotation orientation angle between the instruction block 100 and the controlled block 200 through only a rotation action, and the instruction block 100 cannot be detached from the controlled block 200 to switch the input instructions.

3. A single instruction block 100 is capable of sending a plurality of instructions, respectively.

4. The instruction building block 100 and the controlled building block 200 are built in a particle mode, and the protruding parts 101 and the touch and press switches 201 are conveniently aligned.

5. The gaps between the particle splicing surfaces 300 of the particle building blocks are fully utilized, and the original splicing mode of the particle building blocks is not influenced.

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 from a perspective in one application of the present invention.

Fig. 2 is a schematic view from another perspective in one application of the present invention.

Fig. 3 is a schematic structural diagram of an instruction block of the annular protrusion according to the present invention.

Fig. 4 is a schematic view of the controlled building block adapted to fig. 3 according to the present invention.

FIG. 5 is a schematic diagram of a command block having a projection according to the present invention.

Fig. 6 is a schematic view of the structure of the controlled building block adapted to fig. 5 according to the present invention.

FIG. 7 is a schematic diagram of a command block with two protruding portions according to the present invention.

Fig. 8 is a schematic view of the construction of the controlled building block of the invention adapted to fig. 7.

Fig. 9 is a schematic structural diagram of a command block having two protruding parts in the variation of fig. 7.

Fig. 10 is a schematic view of the controlled building block adapted to fig. 9 according to the present invention.

Fig. 11 is a schematic structural diagram of an instruction block of a strip-shaped protrusion according to the present invention.

Fig. 12 is a schematic view of the construction of the controlled building block of the invention adapted to fig. 11.

Fig. 13 is a schematic diagram of a command block according to another embodiment of the present invention.

Fig. 14 is a schematic diagram of another instruction block according to another application of the present invention.

Fig. 15 is a schematic structural view of the controlled building block adapted to fig. 13 and 14.

Fig. 16 is a schematic view of a controlled building block in yet another application of the present invention.

Fig. 17 is a schematic structural diagram of the instruction block adapted to fig. 16 according to the present invention.

The figures show that:

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will aid those skilled in the art in further understanding the present invention, but are not intended to limit the invention in any manner. 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 invention.

As shown in fig. 1 and fig. 2, the building block system for contact interaction provided in the present invention includes: instruction block 100 and controlled block 200. Adaptive particle building blocks are arranged between the instruction building block 100 and the controlled building block 200; the particle head 400 on the particle splicing surface 300 of the instruction building block 100 is a female head, and the particle splicing surface 300 of the controlled building block 200 is provided with two particle heads 400 which are male heads. Therefore, the instruction block 100 and the controlled block 200 can be axially fixed by means of particle head splicing, and a spliced state is formed. In the splicing state, the grain splicing surface 300 of the instruction block 100 and the grain splicing surface 300 of the controlled block 200 are opposite to each other.

Further, in the two opposite, the granule splicing face 300 of the instruction block 100 is provided with projections 101, eight projections 101 being shown in fig. 1; touch switches 201 are arranged on the particle splicing surface 300 of the controlled building block 200, wherein four touch switches 201 are arranged on the particle splicing surface 300 on the left side of the controlled building block 200 in fig. 2, and eight touch switches 201 are arranged on the particle splicing surface 300 on the right side of the controlled building block 200 in fig. 2. When the instruction block 100 and the controlled block 200 are in a connected state, if the protrusion 101 of the instruction block 100 is aligned with the push switch 201 of the controlled block 200, the push switch 201 is pressed by the protrusion 101 and is triggered. The controlled building block 200 comprises a circuit, wherein the circuit collects trigger information of the touch switch 201 and obtains an instruction according to the trigger information.

In a preferred embodiment, the number of the touch switches 201 is plural, and the command is a coded command, and specifically, if the number of the touch switches 201 is two, three different commands, i.e., a command that is triggered, another command that is not triggered, and a command that is not triggered, may be received according to whether the two touch switches 201 are triggered respectively. If the triggered is marked as 1 and the non-triggered is marked as 0, four codes are obtained, namely 11, 10 and 01. If the number of the trigger switches 201 is larger than two, more kinds of codes can be obtained. In a specific application, there is a controlled block 200, there are two touch switches 201 on a particle splicing surface 300 on the controlled block 200, there are three instruction blocks 100, which are respectively marked as an upper block, a middle block, and a lower block, when the four instruction blocks 100 are spliced to the controlled block 200, two trigger switches 201 are respectively triggered, one triggers the other without triggering, and the other does not trigger, and the corresponding instructions to the controlled block 200 are 11, 10, and 01, respectively, then the controlled block 200 plays voices through a circuit in real time or in a manner after power-up, respectively: the upper reaches of the Yangtze river, the midstream of the Yangtze river and the lower reaches of the Yangtze river.

In the preferred embodiment shown in fig. 3 and 4, the protruding portion 101 of the command block 100 extends in the circumferential direction to form a ring structure; the number of the protruding parts 101 of the instruction block 100 is multiple, and the number of the touch switches 201 of the controlled block 200 is multiple and is greater than or equal to the number of the protruding parts 101, wherein the touch switches 201 are distributed at intervals in the radial direction. For example, fig. 3 shows three projections 101, and fig. 4 shows four tact switches 201. A plurality of annular-structure bulges 101 are nested in sequence to form concentric rings.

Since the protrusion 101 is of a closed annular structure, regardless of the orientation angle between the protrusion 101 and the touch switch 201, as long as the protrusion 101 and the touch switch 201 are at radial positions, the protrusion 101 can trigger the touch switch 201 when the instruction block 100 is spliced with the controlled block 200. Namely, when the instruction block 100 and the controlled block 200 are in a splicing state, at least under one relative rotation orientation angle a, the protrusion 101 of the instruction block 100 triggers the touch switch 201 of the controlled block 200; in the preferred embodiment, the relative rotation azimuth angle a may be any angle from 0 to 360 degrees.

To achieve the input of the coding commands, in a set of toys, a controlled block 200 as shown in fig. 4 may be configured, and a second fourth power minus a command block 100 may be configured to form a second fourth power minus a four-bit coding command, respectively. Accordingly, in these command bricks 100, there is only one annular projection 101, there are bricks with two annular projections 101, three annular projections 101, or four annular projections 101.

In a variation, the number of the protruding portions 101 of the instruction block 100 is one, and the number of the touch switches 201 of the controlled block 200 is one or more, wherein the touch switches 201 are distributed at intervals in the radial direction.

As shown in fig. 5 and 6, the protrusion 101 of the command block 100 is pointed; the number of the protruding parts 101 of the instruction block 100 is one, and the number of the touch switches 201 of the controlled block 200 is plural, wherein the plurality of touch switches 201 are distributed at intervals in the circumferential direction. In a variation, the number of touch switches 201 of the controlled block 200 is one.

When the instruction block 100 and the controlled block 200 are in a splicing state, the orientation angle d1 of the protrusion 101 is the same as the orientation angle a, and at least under one relative rotation orientation angle a, the protrusion 101 of the instruction block 100 triggers the touch switch 201 of the controlled block 200. When the instruction block 100 and the controlled block 200 are in a splicing state, the orientation angle d1 of the protrusion 101 is the same as the orientation angle B, and at least under another relative rotation orientation angle B, the protrusion 101 of the instruction block 100 avoids the touch switch 201 of the controlled block 200. When the instruction block 100 and the controlled block 200 are in a spliced state, the orientation angle d1 of the protrusion 101 is the same as the orientation angle C, and at least under another relative rotation orientation angle C, the protrusion 101 of the instruction block 100 also triggers the touch switch 201 of the controlled block 200. Different touch switches 201 are arranged between the touch switches 201 which are respectively triggered under the relative rotation azimuth angle A and the relative rotation azimuth angle C.

When the instruction block 100 and the controlled block 200 are in a splicing state, a gap exists between the particle splicing surface 300 of the instruction block 100 and the particle splicing surface 300 of the controlled block 200, so as to avoid triggering the touch switch 201. The height of the protrusion 101 is smaller than the height of the gap and larger than the distance between the top end and the particle splicing surface 300 of the instruction building block 100 when the touch switch 201 is not triggered. When the user circumferentially rotates to adjust the relative rotation azimuth angle between the instruction block 100 and the controlled block 200: the protrusion 101 of the command block 100 moves along the circumferential direction along with the rotation, and can trigger different touch switches 201 on the controlled block 200.

As shown in fig. 7 and 8, which are a variation of the preferred embodiment of the present invention shown in fig. 5 and 6, the command block 100 has a plurality of dot-shaped protrusions 101, and the controlled block 200 has a plurality of touch switches 201, which are greater than or equal to the number of the protrusions 101, wherein the plurality of touch switches 201 are circumferentially spaced.

When the instruction block 100 and the controlled block 200 are in a splicing state, the orientation angle d2 of the protrusion 101 is the same as the orientation angle a, and at least under one relative rotation orientation angle a, the protrusion 101 of the instruction block 100 triggers the touch switch 201 of the controlled block 200. When the instruction block 100 and the controlled block 200 are in a splicing state, the orientation angle d2 of the protrusion 101 is the same as the orientation angle B, and at least under another relative rotation orientation angle B, the protrusion 101 of the instruction block 100 avoids the touch switch 201 of the controlled block 200. When the instruction block 100 and the controlled block 200 are in a spliced state, the orientation angle d2 of the protrusion 101 is the same as the orientation angle C, and at least under another relative rotation orientation angle C, the protrusion 101 of the instruction block 100 also triggers the touch switch 201 of the controlled block 200. Different touch switches 201 are arranged between the touch switches 201 which are respectively triggered under the relative rotation azimuth angle A and the relative rotation azimuth angle C.

As shown in fig. 9 and 10, which are a variation of the preferred embodiment shown in fig. 7 and 8 of the present invention, the number of the dot-shaped protrusions 101 of the command block 100 is plural, and the number of the touch switches 201 of the controlled block 200 is plural and is greater than or equal to the number of the protrusions 101, wherein the plurality of touch switches 201 are distributed at intervals in the circumferential direction.

When the instruction block 100 and the controlled block 200 are in a splicing state, the orientation angle d3 of the protrusion 101 is the same as the orientation angle a, and at least under one relative rotation orientation angle a, the protrusion 101 of the instruction block 100 triggers the touch switch 201 of the controlled block 200. When the instruction block 100 and the controlled block 200 are in a spliced state, the orientation angle d3 of the protrusion 101 is the same as the orientation angle B, and at least under another relative rotation orientation angle B, the protrusion 101 of the instruction block 100 avoids the touch switch 201 of the controlled block 200. When the command block 100 and the controlled block 200 are in a connected state, the orientation angle d3 of the protrusion 101 is the same as the orientation angle C, and at least under another relative rotation orientation angle C, the protrusion 101 of the command block 100 also triggers the touch switch 201 of the controlled block 200. Among the touch switches 201 that are triggered at the relative rotation azimuth angle a and the relative rotation azimuth angle C, the same touch switches 201 exist.

As shown in fig. 11 and 12, the protrusion 101 of the instruction block 100 is a bar. With reference to the annular protrusion 101 in fig. 3, the dot-shaped protrusion 101 in fig. 5, and the strip-shaped protrusion 101 in fig. 11, the annular protrusion 101 has no requirement for the orientation angle between the protrusion 101 and the touch switch 201, and can be triggered, the dot-shaped protrusion 101 requires a higher requirement for the orientation angle between the protrusion 101 and the touch switch 201, and the requirement for the range angle between the protrusion 101 and the touch switch 201 by the strip-shaped protrusion 101 is higher than that of the annular protrusion 101 and lower than that of the dot-shaped protrusion 101. Accordingly, on a certain particle splicing surface 300, the dot-shaped protrusions 101 can provide more coding instructions, the annular protrusions 101 provide fewer coding instructions, and the number of coding instructions that can be provided by the strip-shaped protrusions 101 is higher than that of the annular protrusions 101 and lower than that of the dot-shaped protrusions 101.

As shown in fig. 13, 14 and 15, a set of two command blocks 100 and one controlled block 200 are shown.

The instruction building block 100 is provided with indication information of the convex part arrangement and/or indication information of the convex part orientation; the projection type indication information indicating the distribution type of the projections 101; the projection orientation indicating information is used to indicate the distribution orientation of the projections 101. As shown in fig. 13, a top surface of the instruction block 100 is shown, and the protrusion 101 on the bottom surface is shown in a perspective view by a dotted line, wherein the text direction of text advance is the protrusion direction indication information, and the text advance is the protrusion type indication information, so that the user can know the situation of the bottom protrusion or the instruction that the instruction block 100 can be spliced to the controlled block 200 even if the bottom protrusion 101 is not visible. As shown in fig. 14, a top surface of the instruction block 100 is shown, and a protrusion 101 on a bottom surface is shown in a perspective view with a dotted line, wherein a character direction in which characters recede is a protrusion direction indication information, and a character recedes is a protrusion type indication information.

Further, as shown in fig. 15, touch switch type indication information and touch switch orientation indication information are provided on the controlled building block 200; the touch switch type indication information is used for indicating the distribution type of the touch switches 201, for example, the side of the controlled block 200 is marked with the direction of the character toy car, so that a user knows that the controlled block 200 is matched with the instruction block 100 for moving forward and backward; the push switch direction indication information is used to indicate the distribution direction of the push switches 201, for example, an arrow on the side of the controlled block 200 shown in fig. 15, and when the character direction of the instruction block 100 corresponds to the azimuth angle of the arrow on the side of the controlled block 200, the user can apply a forward instruction and a backward instruction to the controlled block 200 when the azimuth angle is referred to.

As shown in fig. 16 and 17, which are variations of the embodiments shown in fig. 13, 14, and 15, a plurality of projection type indication information is provided on the instruction block 100, where the plurality of projection type indication information are respectively used for indicating distribution types of different sets of projections 101. As shown in fig. 17, four types of protruding portions indicating information, namely, instructions for broadcasting a, B, C, and D in voice, are provided on one instruction block 100, each instruction corresponds to a type indicating one protruding portion, and the type of protruding portion includes the number of protruding portions and the distribution position of the protruding portions in the radial direction. Thus, one instruction block 100 in fig. 17 can give four instructions to the controlled block 200 in fig. 16 at different relative rotation orientation angles, and after receiving the voice broadcasts a, B, C, and D, the controlled instruction block 200 broadcasts english reading of apple, boy, cat, and dog, respectively.

When the instruction block 100 and the controlled block 200 are in a splicing state, a gap exists between the particle splicing surface 300 of the instruction block 100 and the particle splicing surface 300 of the controlled block 200, so as to avoid triggering the touch switch 201. The height of the protrusion 101 is smaller than the height of the gap and larger than the distance between the top end and the particle splicing surface 300 of the instruction building block 100 when the touch switch 201 is not triggered.

When the instruction block 100 and the controlled block 200 are in the splicing state, the user is allowed to circumferentially rotate to adjust the relative rotation orientation angle between the instruction block 100 and the controlled block 200, so that: the convex part 101 and the touch switch 201 which are triggered by mutual contact change to be separated from each other; alternatively, the mutually separated protrusion 101 and the touch switch 201 are changed to be triggered by mutual contact. When the user rotates the adjustment instruction block 100 circumferentially to adjust the relative rotation azimuth angle between the controlled block 200: the touch switch 201 of the controlled toy block 200 moves in the circumferential direction along with the rotation, and can be triggered by different protrusions 101 on the command toy block 100. For example, after the instruction block 100 shown in fig. 17 is spliced to the controlled block 200 shown in fig. 16 by the particles, the instruction block 100 can be changed in relative orientation angle in the circumferential direction with respect to the controlled block 200 by the axis formed by the particles around the male and female heads, and as the instruction block 100 shown in fig. 17 rotates, the four sets of protrusions 101, a, B, C, and D, on the instruction block 100 can sequentially trigger the touch switches 201 on the controlled block 200 shown in fig. 16 in groups. Throughout the rotation, the instruction block 100 is always spliced to the controlled block 200, and is not required to be spliced again after being detached. The particle building blocks are round particles, such as round male heads and round female heads shown in fig. 1, fig. 3 and fig. 4.

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 (15)

1. A touch interactive construction system, comprising: an instruction block (100) and a controlled block (200);

adaptive particle building blocks are arranged between the instruction building block (100) and the controlled building block (200);

a protruding part (101) is arranged on the particle splicing surface (300) of the instruction building block (100);

a touch switch (201) is arranged on the particle splicing surface (300) of the controlled building block (200);

when the instruction building block (100) and the controlled building block (200) are in a splicing state, at least under one relative rotation azimuth angle A, the protruding part (101) of the instruction building block (100) triggers the touch switch (201) of the controlled building block (200);

when the instruction building block (100) and the controlled building block (200) are in a splicing state, a gap exists between the particle splicing surface (300) of the instruction building block (100) and the particle splicing surface (300) of the controlled building block (200) so as to avoid triggering the touch switch (201);

when the instruction building block (100) and the controlled building block (200) are in a splicing state, allowing a user to circumferentially rotate and adjust the relative rotation azimuth angle between the instruction building block (100) and the controlled building block (200), so that:

the convex part (101) and the touch switch (201) which are triggered by mutual contact change to be separated from each other; or

The mutually separated convex parts (101) and the touch switch (201) are mutually contacted and triggered.

2. Touch interactive construction system according to claim 1, characterized in that the controlled construction (200) comprises a circuit, wherein the circuit collects the trigger information of the touch switch (201) and derives the command from the trigger information.

3. Building block system for touch interaction according to claim 2, characterized in that the number of touch switches (201) is multiple and the command is a coded command.

4. The touch-interactive building block system according to claim 1, characterized in that the projections (101) of the command building blocks (100) extend circumferentially in a ring-like configuration;

the number of the protruding parts (101) of the instruction building block (100) is one, the number of the touch switches (201) of the controlled building block (200) is one or more, and a plurality of touch switches (201) are distributed at intervals in the radial direction; or

The number of the protruding parts (101) of the instruction building block (100) is multiple, the number of the touch switches (201) of the controlled building block (200) is multiple and is larger than or equal to the number of the protruding parts (101), and the touch switches (201) are distributed at intervals in the radial direction.

5. Touch-interactive construction system according to claim 4, wherein a plurality of ring-shaped structured protrusions (101) are nested one within the other.

6. Touch interactive block system according to claim 1, characterized in that, when the command block (100) is in a state of being spliced to the controlled block (200), the projection (101) of the command block (100) is directed to avoid the touch switch (201) of the controlled block (200) at least at another relative rotational orientation angle B.

7. A touch-interactive construction system according to claim 6, characterized in that the projection (101) of the command construction (100) also activates the touch switch (201) of the controlled construction (200) at least at a further relative rotational orientation C when the command construction (100) is in a connected state with the controlled construction (200);

different touch switches (201) exist between the touch switches (201) which are respectively triggered under the relative rotation azimuth angle A and the relative rotation azimuth angle C.

8. Touch interactive construction system according to claim 7, characterized in that the same tactile switches (201) are present between the tactile switches (201) activated in the relative rotation orientation angle A and the relative rotation orientation angle C, respectively.

9. Building block system for contact interaction according to claim 6 or 7, characterized in that the projections (101) of the command building block (100) are point-shaped or bar-shaped;

the number of the protruding parts (101) of the instruction building block (100) is one, the number of the touch switches (201) of the controlled building block (200) is one or more, and the touch switches (201) are distributed at intervals in the circumferential direction and/or the radial direction; or

The number of the protruding parts (101) of the instruction building block (100) is multiple, the number of the touch switches (201) of the controlled building block (200) is multiple and is larger than or equal to the number of the protruding parts (101), and the touch switches (201) are distributed at intervals in the circumferential direction and/or the radial direction.

10. Building block system for touch interaction according to claim 1, characterized in that a bulge arrangement indication and/or a bulge orientation indication is provided on the instruction building block (100);

the projection type indication information is used for indicating the distribution type of the projections (101);

the convex part orientation indicating information is used for indicating the distribution orientation of the convex parts (101).

11. Building block system for touch interaction according to claim 10, characterized in that a touch switch type indication and/or a touch switch orientation indication is provided on the controlled building block (200);

the touch switch type indication information is used for indicating the distribution type of the touch switches (201);

and the touch switch orientation indication information is used for indicating the distribution orientation of the touch switches (201).

12. Building block system for touch interaction according to claim 10, wherein a plurality of projection type indicators are provided on the instruction building block (100), wherein the plurality of projection type indicators are each used to indicate a distribution type of a different set of projections (101).

13. Touch-interactive block system according to claim 1, characterized in that the height of the protrusion (101) is greater than the distance between the tip and the grain-splicing face (300) of the command block (100) when the touch switch (201) is not activated.

14. The touch interactive construction system of claim 1, wherein the granular construction employs round granules.

15. A touch-interactive construction system according to claim 14, wherein, when the user rotates circumferentially the adjustment command construction (100) and the controlled construction (200) by a relative rotational orientation:

the protruding part (101) of the instruction building block (100) moves along the circumferential direction along with the rotation, and different touch switches (201) on the controlled building block (200) can be triggered; and/or

The touch switch (201) of the controlled building block (200) moves along the circumferential direction along with rotation and can be triggered by different protruding parts (101) on the command building block (100).

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