BR102013027804A2 - modularized contact conductor building block type - Google Patents

Abstract

type of modularized contact conductive building block. A building block includes: a brick, at least one pair of securing pins, a circuit board, and a base. The brick includes at least a pair of buttons designed from an upper part of it. A button hole penetrates through each button. The fixing pin includes an insulating part and a conductive part. the upper part of the insulating part is disposed in the button hole and the conductive part is arranged in the insulating part. The conductive part has an insertion electrode, a contact electrode and a connecting electrode extended from an upper part, one side and a lower part respectively. The circuit board and base are coated on the mounting pins. The circuit board includes a positive electrode circuit and a negative electrode circuit respectively in contact with a pair of retaining pins and a functional unit electrically connected with both electrode circuits.

Description

"TYPE OF CONSTRUCTION BLOCK MODULAR CONTACT DRIVER".

BACKGROUND OF THE INVENTION 1. Field of the Invention. The present invention relates generally to a building block and, in particular, to a type of modularized contact conductive building block. 2. Prior Techniques, New types of toys that can stimulate intelligence, such as building blocks, are developed with the advancement of the electronics industry. For example, the conventional building block further includes a circuit board, LED lights, speakers, etc. arranged thereon. After a plurality of building blocks were connected together, the building blocks would emit light or play music, providing more entertainment and fun.

A building block with conventional electrical connection, such as Taiwan Utility Model Patent No. M408402 includes mounting studs mounted on a circuit board. The anchor pin includes a positive conductor unit and a negative conductor unit. Each negative and positive conductive unit has a metal cable. Metal cables are soldered to the circuit board and connected to the electronics by the circuit board.

However, the positive and negative electrodes are simultaneously mounted on the fixing pin of the conventional light-emitting building block. Thus, the clamping pin has many components and a complex structure. In addition, it is necessary to solder the negative and positive conductor unit to the circuit board; However, the welding process, besides being quite expensive, is also not environmentally friendly.

In addition, both the positive and negative electrode are mounted in the same button hole. If any foreign metal is inside the button or the button is compressed and deformed, it is likely that both electrodes will contact each other to form the electrical connection. A short circuit could occur.

SUMMARY OF THE INVENTION

To overcome the disadvantages of conventional designs that have many components, a complex structure, the need for a welding process and a short circuit risk, a main objective of the present invention is to provide a type of modularized conductive contact building block that has Few components, simple structure, improved safety and welding free. In order to achieve the goal, a type of modularized contact conductive building block according to the present invention includes: a hollow brick, at least one pair of securing pins, a circuit board and a base. The brick includes at least a pair of buttons projecting from an upper part thereof and an opening defined in a lower part thereof and communicating with an inner part thereof. A button hole penetrates through the button and communicates with the inside of the brick. At least one pair of securing pins are disposed in the button holes respectively. The fixing pin includes an insulating part and a conductive part. The insulating part includes a mounting hole vertically penetrating through an inner portion thereof and an extension groove formed on one side thereof. The axeansa © slot communicates with the mounting hole. The conductive part is disposed in the mounting hole of the insulating part. An insertion electrode is. located on an upper part of the conductive part and projected out of the mounting hole. A contact electrode is horizontally extended from one side of the conductive part. The contact electrode penetrates and protrudes out of the extension slot. A connecting electrode is vertically extended from a bottom of the conductive part. The circuit board is disposed on the inside of the brick and covered in the fixing pins. The circuit board has a positive electrode circuit, a negative electrode circuit, and a functional unit. The positive electrode circuit is in contact with the contact electrode of a first clamping pin of each pair of clamping pins, the first clamping pin being defined as a positive electrode clamping pin. The negative electrode circuit is in contact with the contact electrode of a second clamping pin of each pair of clamping pins, the second clamping pin being defined as a negative electrode clamping pin. The functional unit is electrically connected to the negative and positive electrode circuits. The base is arranged on the inner part of the brick. The base includes at least one pair of through holes, allowing the securing pins to pass through. The type of modularized conductive contact building block according to the present invention provides the securing pins having the same structure. In addition, the insulating part and the fixing pin conductive part have simple structures and are easy to assemble. Thus, the present invention can effectively simplify structural designs and greatly reduce the manufacturing cost. Furthermore, according to the first and second application of the present invention; the tops of the clamping pins are pressed against the brick, the contact electrodes of the clamping pins are pressed against the circuit board, the circuit board is pressed against the base and the base is fixed to the brick. Thus, the conductive parts are safely pressed against and in contact with the circuit board and do not need to electrically connect the conductive part with the circuit board by the welding process. Thus, the building block according to the present invention has the advantage of being environmentally friendly and labor saving.

In addition, the positive and negative mounting pin electrodes are determined by the conductive part contact electrode when in contact with the positive electrode circuit or the circuit board negative electrode circuit; thus, after the clamping pins are assembled, the clamping pins can be clearly classified as the positive electrode clamping pin or the negative electrode clamping pin. And even if foreign metal falls into the button hole or if the button is compressed and deformed, it will not short circuit. Therefore, the safety of the building blocks is guaranteed.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be apparent to those skilled in the art by reading the following detailed description of preferred applications thereof with reference to the accompanying drawings, in which: Fig. 1 is a perspective view showing a type of conductive building block. modularized contact according to a first application of the present invention; Fig. 2 is an enlarged view showing a type of modularized contact conductive building block according to the first application of the present invention; Fig. 3 is an enlarged view showing a clamping pin according to the first application of the present invention; Fig. 4 is a vertical cross-sectional view showing the mounting pins mounted on a circuit board according to the first application of the present invention; Fig. 5 is a horizontal cross-sectional view showing the fixing pins mounted on the circuit board according to the first application of the present invention; Fig. 6 is a cross-sectional view showing two of the types of modularized contact conductive building block according to the first application of the present invention connected together; Fig. 7 is an enlarged view showing a clamping pin according to a second application of the present invention; Fig. 8 is a vertical cross-sectional view showing the mounting pins mounted on the circuit board according to the second application of the present invention; Fig. 9 is a cross-sectional view showing two of the types of modularized contact conductive building block according to the second application of the present invention connected together; and Fig. 10 is a perspective view showing a type of modularized conductive contact building block according to a third application of the present invention.

DETAILED DESCRIPTION OF PREFERRED APPLICATION

With reference to Figs. 1 and 2, a type of modularized contact conductive building block according to a first preferred application of the present invention includes a brick 10, at least one pair of securing pins 20, a circuit board 30 and a base 40. Brick 10 is a light transmitting hollow cube. The brick 10 includes at least a pair of ring-shaped buttons 11 projected from an upper part thereof. A hole of button 12 penetrates through button 11 and communicates with an inner part of brick 10. An upper edge of an inner wall of button hole 12 extends inwardly to form a ring retaining edge 13. An opening is defined on a lower part of brick 10 and communicates with the inner part of brick 10. Preferably, the top of brick 10 is designed to form two pairs of buttons that are symmetrically arranged in a matrix.

At least one pair of locking pins 20 are disposed in the button holes 12 of brick button 11 and the upper parts of the locking pins 20 are pressed against the ring retaining edges 13 (as shown in Fig. 6). respectively. According to the first application, brick 10 has two pairs of securing pins 20 symmetrically arranged in a die. Referring to Fig. 3, each locking pin 20 includes an insulating part 21 and a conductive part 22. An upper part of the insulating part 21 is located in the button hole 12. The insulating part 21 includes a vertically mounting hole 210 which penetrates through an inner portion thereof and an extension slot 211 formed on one side of a lower portion thereof. The extension slot 211 communicates with the mounting hole 210. The insulating part 21 according to the first application is only one type of the present invention. According to another type, the insulating part 21 may have two halves of front pieces that join together. In yet another type, the insulating part 21 may also have the upper and lower tubes connected to each other by insertion. In addition, the top and bottom of the insulating part 21 of the securing pin 20 may be formed into a circle or a rectangle. The types and shapes of the clamping pins 20 according to the present invention are not limited. The conductive part 22 is disposed in the mounting hole 210 of the insulating part 21. An insertion electrode 220 is located on an upper part of the conductive part 22 and projected out of the mounting hole 210. A contact electrode 221 is horizontally extended to from one side of a bottom of the conductive part 22. The contact electrode 221 penetrates and protrudes out of the extension slot 211. A connecting electrode 222 is vertically extended from the bottom of the conductive part 22 and misaligned with the insertion electrode 220.

With reference to Figs. 2, 4 and 5, circuit board 30 is disposed within brick 10. Circuit board 30 includes a plurality of through-holes 31 to cover the corresponding securing pins 20, respectively. In addition, circuit board 30 has a positive electrode circuit 32 and a negative electrode circuit 33 (as shown in Fig. 5). Each pair of locking pins 20 have a first locking pin and a second locking pin. The contact electrode 221 of the conductive part 22 of the first clamping pin of each pair of clamping pins 20 is pressed against the circuit board 30 so that the contact electrode 221 of the first clamping pin is in contact and electrically connected. with positive electrode circuit 32. Because it is in contact with positive electrode circuit 32, the first retaining pin is defined as a positive electrode retaining pin 20A. The contact electrode 221 of the conductive part 22 of the second securing pin of each pair of securing pins 20 is pressed against a circuit board 30 so that the contact electrode 221 of the second securing pin is in contact and electrically connected. with negative electrode circuit 33. Because it is in contact with negative electrode circuit 33, the second retaining pin is defined as a negative electrode retaining pin 20B. Preferably, the positive electrode clamping pins 20A and the negative electrode clamping pins 20B are symmetrically arranged in a matrix and cross-linked such that both clamping pins are immediately adjacent to both sides of the positive electrode clamping pin. 20A are the negative electrode fixing pins 20B and both fixing pins immediately adjacent to both sides of the negative electrode fixing pin 20B are positive electrode fixing pins 20A. Circuit board 30 further includes a functional unit 34 connected to the positive electrode circuit 32 and negative electrode circuit 33. Preferably, functional unit 34 is an LED light or sound generating device.

Referring to Fig. 2, the base 40 is disposed on the inner part of the brick 10. In addition, the base 40 is located under the circuit board 30 and pressed against the bottom of the circuit board 30. The base 40 includes, at least one pair of through holes 41 and the lower portions of the securing pins 20 penetrate through through holes 41 to pass through base 40. Preferably, base 40 is cast.

Referring to Fig. 6, when mounting two building blocks according to the first application, the lower part of the positive electrode fixing pin 20A in the upper brick 10 is correspondingly inserted into the upper part of the positive electrode fixing pin 20A in the bottom brick 10 and lead electrode 222 of lead piece 22 on positive upper lead pin 20A contacts lead insert 220 of lead 22 on lower positive lead pin 20A, thereby electrically connecting the positive electrode fixing pins 20A in the upper and lower bricks 10 together. At this time, the lower part of the negative electrode fixing pin 20B in the upper brick 10 is correspondingly inserted into the upper part of the negative electrode fixing pin 20B in the lower brick 10 and the connecting electrode 222 of the conductive part 22 in the fixing pin The upper electrode 20B contacts the insertion electrode 220 of the conductive part 22 on the lower positive electrode fixing pin 20B, thereby electrically connecting the positive electrode fixing pins 20B on the upper and lower bricks 10 to each other.

After the building blocks are connected together, the positive electrode fixing pin 20A and the negative electrode fixing pin 20B of the upper or lower part of the building block are respectively connected to a positive electrode and an electrode. power supply, thus providing power to the functional unit 34 to emit light or generate sound.

A type of modularized conductive contact building block according to the second application of the present invention has a structure essentially similar to that of the first application. However, the type of locking pin 20C is slightly different from the first application. With reference to Figs. 7 and 8, a conductive part 22C is disposed in a mounting hole 210C of the insulating part 21C. An insertion electrode 220C is located on an upper part of the conductive part 22C and projected out of the mounting hole 210C. An upper end of the insertion electrode 220C is engaged to form an insertion hole 223C. A contact electrode 221C is horizontally extended from one side of a lower part of the conductive part 22C. The contact electrode 221C penetrates and protrudes out of the extension slot 211C. A connecting electrode 222C is vertically extended from the bottom of the conductive part 22C and located corresponding to the insertion hole 223C. The diameter of the connecting electrode 222C corresponds to the diameter of the insertion hole 223C.

Referring to Fig. 9, when mounting two building blocks according to the second application, the connecting electrode 222C of the conductive part 22C in the upper brick 10C is inserted into the insertion hole 223C of the conductive part 22C in the lower brick 10C, thus by electrically connecting the conductive parts 22C to the top and bottom bricks 10C together. Except for the description mentioned above, the second application has the same structure, assembly method and functions as the first application. Thus, the descriptions of the structure, assembly method and functions of the second application are not repeated here again.

With reference to Figs. 10, a type of modularized contact conductive building block according to a third application has a structure essentially similar to that of the first application. However, a first button of at least one pair of buttons 11D of brick 10D is formed into a circle and a second button 11D is formed into a rectangle. When brick 10D has a plurality of pairs of buttons 11D, the circular and rectangular buttons 11D are symmetrically arranged in a matrix and crossed with each other, so that both buttons 11D immediately adjacent to both sides of circular button 11D are rectangular buttons. and both 11D buttons immediately adjacent to both sides of the rectangular button are the 11D circular buttons. Except for the description mentioned above, the third application has a structure, assembly method and functions similar to those of the first application. Thus, the descriptions of the structure, assembly method and functions of the third application are not repeated here again. It is easy to distinguish the locations of the positive and negative electrode clamping pins from the appearances of the 11D buttons according to the third application. Thus, the building block according to the third application is equipped with an error-proof mounting function. For example, the positive electrode clamp pin is configured as a circular 11D button and the negative electrode clamp pin is configured as a rectangular 11D button. By connecting building blocks, can the user connect conectar ir and * π i 5? the? »nino 5? cic * fi Hcí p »1 pt * tocio pnt rp qí. p> conppt-rir * £ ** JL »V · *« A »* —2 Ca Vm / k? mI * X X '—AC? JL '1. > y · Ci ws * / V-- -A- xx. v · ^ Jw W w -A »L.« A * v W n * # AAW A. Cr «1» V ** θ 'AA Cr V ** CA JL. the negative electrode fixing pins to each other. This may prevent the loss of the positive electrode retaining pin connection to the negative electrode retaining pin connection. Whether it is the positive electrode fixing pin 20A or the negative electrode fixing pin 20B, the modularized contact type of the conductive building block according to the present invention comprises the positive and negative electrode fixing pins having the same structure. The insulating part 21 and the conductive part 22 of the clamping pin 20 have simple and easily assembled structures, so complex shapes are significantly simplified and manufacturing costs significantly reduced.

Also, because the positive and negative electrodes of the clamping pin 20 are determined by the contact electrode 221 of the conductive part 22 when in contact with the positive electrode circuit 32 or the negative electrode circuit 33 of circuit board 30. Then , when the contact electrode 221 contacts the positive electrode circuit 32, the clamping pin 20 is defined as the conductive part of the clamping pin 20A. And, when the contact electrode 221 contacts the negative electrode circuit 33, the securing pin 20 is defined as the negative electrode securing pin 20B. Thus, unlike conventional designs which have both positive and negative electrodes simultaneously disposed on each clamping pin, each clamping pin according to the present invention has only a single electrode. After mounting the clamping pins 20, each clamping pin 20 according to the present invention can be clearly classified as positive or negative electrode. Therefore, there is no need to worry about foreign metal falling into the hole in button 12 or the buttons being compressed and deformed, which causes the positive and negative electrodes to contact each other and short-circuit. In this way the safety of the building blocks is increased.

While the present invention has been described with reference to the respective preferred applications, it is apparent to those skilled in the art that a variety of modifications and changes may be made without departing from the scope of the present invention, which is intended to be defined by the appended claims.

Claims (8)

1. A type of modularized conductive contact building block, comprising: a hollow brick having at least one pair of buttons projecting from an upper part thereof and an opening defined in a lower part thereof and communicating with one another. an inner part thereof, a button hole penetrating through the button and communicating with the inner part of the brick; at least one pair of securing pins arranged in the button holes, the securing pin including an insulating part and a conductive part, a mounting hole that penetrates through the insulating part, an extension groove formed on one side of the insulating part and communicating with the mounting hole, the conductive part disposed in the insulating part mounting hole, a conductive part liner projected out of the mounting hole to form an insertion electrode, a contact electrode horizontally extended from one side of the conductive part, the contact electrode penetrating through and projecting out of the extension slot and a connecting electrode extended from a lower end of the conductive part; A circuit board disposed in the brick and cladding in the securing pins, the circuit board including a positive electrode circuit, a negative electrode circuit, and a functional unit, the positive electrode circuit contacted with a first contact pin contact electrode. clamping of each pair of clamping pins and the first clamping pin being defined by a positive electrode clamping ein ©, the negative electrode circuit contacted with the contact electrode of the second clamping pin of each pair of clamping pins and the second clamping pin being defined with the negative electrode clamping pin, the functional unit electrically connected with the positive and negative electrode circuits; and A base disposed at the lower end of the brick, the base including at least one pair of holes through which the securing pins are coated. The building block according to claim 1, characterized in that the conductive part connection electrode is misaligned with the conductive part insertion electrode. The building block according to claim 1, characterized in that the insertion electrode of the conductive part includes an insertion hole formed in an upper part thereof and a downwardly extending connection electrode location corresponds to the insertion hole. The building block according to any one of claims 1 to 3, characterized in that the functional unit includes an LED light. The building block according to claim 4, characterized in that the upper edge of the inner wall of the button knob hole extends inwardly to form a ring-shaped retaining edge, an upper part of the securing pin is pressed against the housing. retaining ring-shaped edge. The building block according to any one of claims 1 to 3, characterized in that the upper end of the inner wall of the button knob hole extends inwardly to form a ring retaining edge, an upper part of the pin. be pressed against the ring retaining edge. by the first button of at least one pair of buttons having the shape of a circle and a second button of at least one pair of buttons having the shape of a rectangle . The mounting block according to claim 5, characterized in that the first button of at least one pair of buttons has the shape of a circle and a second button of at least one pair of buttons has the shape of a rectangle. The mounting block according to any one of claims 1 to 3, characterized in that the first button of at least one pair of buttons has a circle shape and a second button of at least one pair of buttons has a rectangle shape.