KR200495862Y1 - Circular connector - Google Patents

Abstract

The present invention provides a toroidal connector. The toroidal connector of the present invention has a male plug and a female socket. The male plug provides a first annular body, a third annular body, a first electrode assembly, and a third electrode assembly. The female socket provides a first base body, a second annular body, a fourth annular body, a second base body, a second electrode assembly, and a fourth electrode assembly. The second base body, the fourth annular body, the second annular body, and the first base body are respectively arranged outward from the center point of the female socket. The male plug and the female socket are engaged by inserting the third annular body between the second annular body and the fourth annular body to realize a non-directional electrical connection.

Description

Toroidal connector {CIRCULAR CONNECTOR}

The present invention relates to the technical field of a connector, and more particularly, to a toroidal connector electrically connected in a non-directional manner.

A conventional connector has a male plug and a female socket, and by combining the male plug and the female socket, it is possible to achieve the purpose of transmitting power and signals.

Conventional connectors are usually performed within a range that can be seen and observed by an operator in order to achieve the purpose of coupling. Therefore, since the positional relationship between the male plug and the female socket can be almost confirmed, it is possible to assist the operator by making the male plug and the female socket to be coupled to each other by the mechanical design of the connector, for example, the mechanical design such as a chamfer angle or an inclined surface. .

However, in a situation where it is applied to some electronic products, it may not be easy to realize an electrical connection while showing the male plug and/or female socket. In other words, there is a problem in that so-called blind fitting cannot be performed between the male plug and the female socket in the conventional connector. In particular, since the conventional connector has a normal directionality, if it is inserted carelessly, the male plug and the female socket may be damaged and need to be replaced, and in severe cases, the electronic product itself may be damaged or destroyed.

Conventional connectors are designed to prevent erroneous insertion, but as a result of further miniaturization of the connector dimensions, such a structure may destroy the structure preventing erroneous insertion if excessive force is applied. This can happen frequently and easily.

In view of this, the present invention proposes a toroidal connector in order to solve the problem or unsolvable problem caused by the conventional connector.

A first object of the present invention is to provide a male plug and a female socket, and to provide a toroidal connector capable of realizing a non-directional blind fitting connection by a male plug and a female socket.

A second object of the present invention is to provide an annular structure in the male plug and the female socket separately in the annular connector, and the corresponding electrode assembly provided in each annular structure is formed by combining a plurality of annular structures. An electrode assembly is capable of realizing at least one of power transmission and control signal transmission between a male plug and a female socket.

A third object of the present invention is to provide that in the annular connector, the number of electrode assemblies provided in the annular structure can be adjusted and set according to the application requirements of the actual product.

A fourth object of the present invention is to provide an independent mode in which, in the annular connector, electrode assemblies of a plurality of annular structures each include independent control signal transmission and/or power transmission.

A fifth object of the present invention is to provide a mixed mode in which, in the annular connector, electrodes of an electrode assembly having an annular structure simultaneously transmit control signals and transmit power.

A sixth object of the present invention is that in the annular connector, the number of electrodes of the electrode assembly provided for each annular structure in the plurality of annular structures may be the same or different, and the electrodes between the plurality of annular structures may be different. It is intended to provide that the position of the assembly is designed in a symmetrical or asymmetrical arrangement.

A seventh object of the present invention is to provide that, in the annular connector, a distance between a plurality of electrodes of an electrode assembly may be an equally spaced distance or an unequal spaced distance.

An eighth object of the present invention is to provide an annular connector that can more easily realize blind fitting characteristics between a male plug and a female socket by using an electrode assembly having a floating structure in an annular structure.

A ninth object of the present invention is to provide, in the annular connector described above, a method in which a plurality of annular structures cover an annular structure of a small size with an annular structure of a large size, for example, the construction of concentric circles is adopted. is doing

A tenth object of the present invention is to provide a male plug having, in the annular connector, a first annular body, a third annular body, a first electrode assembly, and a third electrode assembly.

An eleventh object of the present invention is, in the annular connector, a first base body, a second annular body, a fourth annular body, a second base body, a second electrode assembly, a fourth To provide a female socket having an electrode assembly.

A twelfth object of the present invention is to provide that the toroidal connector is applied to a display field, an automobile field, or other application fields requiring electrical connection.

In order to achieve the above and other objects, the present invention provides a toroidal connector applied to the first circuit board and the second circuit board. The toroidal connector has a male plug and a female socket. The male plug may be connected to the first circuit board. The male plug has a first annular body, a third annular body, a first electrode assembly, and a third electrode assembly. The third annular body is superimposed on the first annular body. A first groove is formed on the inner periphery of the first annular body for installing the first end of the first electrode assembly. A third groove is formed on the inner periphery of the third annular body for installing the second end of the first electrode assembly. A fifth groove is formed on the outer periphery of the first annular body for installing the first end of the third electrode assembly. A seventh groove body is formed on the outer periphery of the third annular body for installing the second end of the third electrode assembly. The female socket may be connected to the second circuit board. The female socket has a first base body, a second annular body, a fourth annular body, a second base body, a second electrode assembly, and a fourth electrode assembly. The second base body, the fourth annular body, the second annular body, and the first base body are respectively arranged outward from the center point of the female socket. A second electrode assembly is provided between the first base body and the second annular body, and a fourth electrode assembly is installed between the fourth annular body and the second base body. In addition, a second groove is formed in the second annular body for installing the first end of the second electrode assembly, and a fourth groove is formed in the fourth annular body for installing the first end of the fourth electrode assembly. Among them, the second groove corresponds to the seventh groove, the fourth corresponds to the third groove, and at least one of the second electrode assembly and the fourth electrode assembly has a floating structure. Among them, after the male plug and the female socket are coupled, the third annular body is inserted between the second annular body and the fourth annular body, so that the second end of the third electrode assembly is electrically connected to the first end of the second electrode assembly. to electrically connect the second end of the first electrode assembly to the first end of the fourth electrode assembly.

In order to achieve the above and other objects, the present invention provides a male plug of an annular connector having a first annular body, a third annular body, a first electrode assembly, and a third electrode assembly. The first annular body has a first groove formed on its inner periphery, and a fifth groove formed on its outer periphery. The third annular body is superimposed on the first annular body. The third annular body has a third groove formed on its inner periphery, and a seventh groove formed on its outer periphery. A first end of the first electrode assembly is installed in the first groove body, and a second end thereof is installed in the third groove body. The first end of the third electrode assembly is installed in the fifth groove body, and the second end thereof is installed in the seventh groove body.

In order to achieve the above and other objects, the present invention provides an annular shape having a first base body, a second annular body, a fourth annular body, a second base body, a second electrode assembly, and a fourth electrode assembly Provides a female socket for the connector. The second annular body is installed in the first base body. A second groove body is formed in the second annular body. The fourth annular body is provided in the second annular body, and the fourth groove body is formed in the fourth annular body. The second base body is installed in the fourth annular body. The second electrode assembly is installed between the first base body and the second annular body, and the first end of the second electrode assembly is installed in the second groove body. Among them, the second electrode assembly has a floating structure. The fourth electrode assembly is installed between the fourth annular body and the second base body, and the first end of the fourth electrode assembly is installed in the fourth groove body. Among them, the fourth electrode assembly has a floating structure. Among them, the second base body, the fourth annular body, the second annular body, and the first base body are respectively arranged outward from the center point of the female socket.

Compared with the existing technology, the annular connector provided by the present invention realizes the convenience of non-directional connection on the operator's side, and the designer designs more than one hundred terminals (that is, the electrodes referred to in the present invention) in a limited space. In addition, the present invention can simultaneously design power transmission and control signal transmission in one annular structure, and separate power transmission design and control signal transmission design in another annular structure separately Since it can be set, it is possible to realize applications in more complex and higher-end fields by enabling designers to design based on the transmission of more terminals and each terminal in a limited space.

1 is a structural schematic diagram of a toroidal connector according to an embodiment of the present invention.
2 is a bottom view illustrating the male plug of the annular connector of FIG. 1 of the present invention.
3 is a top view illustrating the female socket of the annular connector of FIG. 1 of the present invention.
4 is a top view illustrating the second annular body and the first base body of the female socket of FIG. 3 of the present invention.
5 is a top view illustrating a fourth annular body and a second base body of the female socket of FIG. 3 of the present invention.
6 is a schematic diagram for explaining another embodiment of the female socket of FIG. 3 of the present invention.
7A is a top view showing the male plug of the present invention and the female socket of FIG. 1 before coupling.
7B is a cross-sectional side view A-A showing the male plug of the present invention and the female socket of FIG. 7A before coupling.
8 is a side view illustrating a fourth annular body of the female socket of FIG. 3 of the present invention.
9 is a partially enlarged top view illustrating the fourth annular body of FIG. 8 of the present invention.
10 is a side view for explaining the connection of the annular connector of FIG. 1 of the present invention.

Reference is made to Fig. 1, which is a structural schematic diagram of a toroidal connector according to an embodiment of the present invention.

<First embodiment>

In Fig. 1, the toroidal connector 10 is applied to the first circuit board 2 and the second circuit board 4, and its connection method is Fig. 10, a side view illustrating the connection of the toroidal connector of Fig. 1 of the present invention can refer to In one embodiment, the first circuit board 2 may be a part of a display panel (not shown), and the second circuit board 4 is to be installed, for example, on a frame body of a wall (not shown). By combining the male plug 12 installed on the first circuit board 2 and the female socket 14 installed on the second circuit board 4 , the display panel is configured with the male plug 12 of the first circuit board 2 . ) to receive a control signal and a power signal from the female socket 14 .

Referring again to FIG. 1 , the annular connector 10 includes a male plug 12 and a female socket 14 . In FIG. 1 , in addition to the female socket 14 , the male plug 12 includes a first groove body 1222 , a fifth groove body 1224 , a first electrode assembly 126 , and a first electrode assembly 126 . A first end 1262 , a third electrode assembly 128 , and a first end 1282 of the third electrode assembly 128 are shown simultaneously. In addition, in this embodiment, the annular connector 10 is described by taking as an example a circular annular shape, and in another embodiment, the annular connector 10 is also an annular shape such as a rectangular annular shape, an even strained annular shape, an odd strained annular shape, or the like. It could be a chain A detailed description of the male plug 12 may be referred to together with FIG. 2 , and a detailed description of the female socket 14 may be referred to together with FIGS. 3 to 6 .

Reference is made to FIG. 2 , which is a bottom view illustrating the male plug of FIG. 1 of the present invention. In FIG. 2 , the male plug 12 has a first annular body 122 , a third annular body 124 , a second end 1264 of the first electrode assembly 126 , and a third electrode assembly 128 . ), a second end 1284 , a third groove 1242 , a fifth groove 1224 , and a seventh groove 1244 are shown.

Both the first annular body 122 and the third annular body 124 have a circular annular shape, and the diameter of the first annular body 122 is larger than the diameter of the third annular body 124 . In the present embodiment, the third annular body 124 is stacked on top of the first annular body 122 to project the third annular body 124 from the first annular body 122, a schematic diagram of which is shown in Fig. Reference may be made to 7b, which is a schematic diagram showing the coupling of the first annular body 122 and the third annular body 124 .

Referring back to FIG. 2 , in the first annular body 122 , a fifth groove body ( 1224) is formed. Among them, a first end 1282 of the third electrode assembly 128 is soldered to the first circuit board 2 for receiving a control signal and/or a power signal (not shown) from the first circuit board 2 . used to connect Further, the second end 1284 of the third electrode assembly 128 also exits the first annular body 122 of FIG. 2 and is exposed from the seventh groove body 1244 of the third annular body 124 . A first groove body 1222 is formed on the inner periphery of the first annular body 122 in order to install the first end 1262 of the first electrode assembly 126 as shown in FIG. 1 . The first end 1262 of the first electrode assembly 126 is also used for soldering connection to the first circuit board 2 to receive a control signal and/or a power signal (not shown) from the first circuit board 2 . .

As mentioned above, the third annular body 124 may be provided with a third groove body 1242 on its inner periphery in addition to the seventh groove body 1244 being formed on its outer periphery. The third groove 1242 is used to install the second end 1264 of the first electrode assembly 126 .

In the above, the number of the fifth grooves 1224 and the seventh grooves 1244 is greater than or equal to the number of the third electrode assemblies 128 , and the number of the first grooves 1222 and the third grooves 1242 is The number is equal to or greater than the number of the first electrode assemblies 126 .

Referring to FIG. 3, which is a top view illustrating the female socket of FIG. 1 of the present invention. In FIG. 3 , the female socket 14 includes a first base body 142 , a second annular body 144 , a fourth annular body 146 , a second base body 148 , and a second electrode assembly. 1410 and a fourth electrode assembly 1412 are shown. The first base body 142 and the second base body 148 may be fixed to the second circuit board 4 . A second base body 148 , a fourth annular body 146 , a second annular body 144 , and a first base body 142 are respectively arranged outward from the center point of the female socket 14 .

Referring to FIG. 4, which is a top view illustrating the second annular body and the first base body of FIG. 3 of the present invention. In FIG. 4 , the material of the first base body 142 may be, for example, a non-conductive material such as plastic. A plurality of grooves 1422 are formed on the outer periphery of the first base body 142 , and the plurality of grooves 1422 expose the second end 14104 of the second electrode assembly 1410 to the second annular body. It corresponds to the second groove body 1442 of (144). A second end 14104 of the second electrode assembly 1410 is used for soldering connection to the second circuit board 4 to receive a control signal and/or a power signal (not shown) from the second circuit board 4 . . Here, the second electrode assembly 1410 is installed between the first base body 142 and the second annular body 144 . The second electrode assembly 1410, in addition to the above-described second end 14104 exposed from the plurality of grooves 1422, the second electrode assembly 1410 also provides a floating structure and a first end 14102. And, the material of the second electrode assembly 1410 may be, for example, a conductive material such as metal. Among them, the floating structure has a shape similar to the letter S shown in FIG. 4 , and the floating structure is formed between the first end 14102 and the second end 14104 of the second electrode assembly 1410 . and, when an external force acts on the second annular body 144 (or the fourth annular body 146), between the second annular body 144 and the first base body 142 according to the amount of deformation that deforms the floating structure. The amount of displacement can be varied, and the first end 14102 of the second electrode assembly 1410 is exposed from the second groove 1442 , and transmits a control signal and/or a power signal from the second circuit board 4 . In order to be used, the second groove body 1442 is provided corresponding to the seventh groove body 1244 of the third annular body 124 in FIG. 2 .

In addition, the second electrode assembly 1410 includes a plurality of second electrodes. The range of the minimum angle sandwiched between the plurality of second electrodes from the center point O (ie, centrifugal) of the second annular body 144 is the second end 14104 of the second electrode assembly 1410 . It relates to the size of the solder to be soldered to the second circuit board 4, and to put it simply, a short circuit due to interference does not occur between the second ends 14104 adjacent to each other of the second electrode assembly 1410 in the process of soldering connection. Otherwise, the minimum angle θ1 of the second ends 14104 adjacent to each other of the second electrode assembly 1410 may approach 0 degrees. In this specification, the range of the minimum angle θ1 is greater than or equal to 7 degrees will be described as an example.

Referring to FIG. 5, which is a top view illustrating the fourth annular body and the second base body of FIG. 3 of the present invention. In FIG. 5 , the material of the second base body 148 may be, for example, a non-conductive material such as plastic. A plurality of grooves 1482 are formed on the inner periphery of the second base body 148 , and are formed at the bottom of the so-called second base body 148 of FIG. 5 , and the plurality of grooves 1482 is a fourth electrode assembly. Corresponds to the fourth groove 1462 of the fourth annular body 146 to expose the second end 14124 of the 1412 . A second end 14124 of the fourth electrode assembly 1412 is used for soldering connection to the second circuit board 4 to receive a control signal and/or a power signal (not shown) from the second circuit board 4 . . Here, the fourth electrode assembly 1412 is installed between the second base body 148 and the fourth annular body 146 . The fourth electrode assembly 1412, in addition to the above-described second end 14124 exposed from the plurality of grooves 1482, the fourth electrode assembly 1412 also provides a floating structure and a first end 14122 and , The material of the fourth electrode assembly 1412 may be, for example, a conductive material such as metal. Among them, the shape of the floating structure is similar to the letter S shown in FIG. 5 , and the floating structure is formed between the first end 14122 and the second end 14124 of the fourth electrode assembly 1412 . and, when an external force acts on the fourth annular body 146 (or the second annular body 144 ), between the fourth annular body 146 and the second base body 148 according to the amount of deformation that deforms the floating structure. While the amount of displacement can be changed, the first end 14122 of the fourth electrode assembly 1412 is exposed from the fourth groove 1462 , and a control signal and/or a power signal from the second circuit board 4 are transmitted. used to convey Moreover, the 4th groove body 1462 is provided corresponding to the 3rd groove body 1242 of the 3rd annular body 124 of FIG. In another embodiment, reference may be made to FIG. 8, which is a side view illustrating the fourth annular body of FIG. 3 of the present invention. In FIG. 8 , in order to easily install the first end 14122 of the fourth electrode assembly 1412 , the fourth groove 1462 can be designed to express a small plane, and the fourth electrode assembly 1412 is It is provided to fit the first end 14122 to the fourth groove 1462, and the same design can be applied to other grooves of the present invention. 9, which is a partially enlarged top view illustrating the fourth annular body of FIG. 8 of the present invention, may also be referred to. In FIG. 9 , a small flat installation is shown in the fourth groove 1462 , and is used to install the first end 14122 of the fourth electrode assembly 1412 .

The fourth electrode assembly 1412 includes a plurality of fourth electrodes. The range of the minimum angle sandwiched between the plurality of fourth electrodes from the center point O (ie, centrifugal) of the fourth annular body 146 is the second end 14124 of the fourth electrode assembly 1412 . It relates to the size of the solder to be soldered to the second circuit board 4, and simply put, a short circuit due to interference does not occur between the second ends 14124 adjacent to each other of the fourth electrode assembly 1412 in the process of soldering connection. Otherwise, the minimum angle θ2 of the second ends 14124 adjacent to each other of the fourth electrode assembly 1412 may approach 0 degrees. In the present specification, the range of the minimum angle θ2 is greater than or equal to the range of the minimum angle θ1 described above.

The number of the second electrode assemblies 1410 of the above-described second annular body 144 is greater than or equal to the number of the fourth electrode assemblies 1412 of the fourth annular body 146, and the second electrode assembly ( The arrangement position of the second electrode of 1410 and the arrangement position of the fourth electrode of the fourth electrode assembly 1412 may be formed symmetrically, or may be formed asymmetrically. For example, since the installation of the first protrusion assembly 1444 and the second protrusion assembly 1464 of FIG. 3 can divide a plurality of blocks A, B, C and D on the original circle, the current The number of second electrodes of the second electrode assembly 1410 in blocks A, B, C, and D is the same as the number of fourth electrodes of the fourth electrode assembly 1412 . However, in other embodiments, there are cases where the arrangement position does not exist other than a symmetrical block, for example, the second electrode and/or the fourth electrode are only in the diagonal blocks of blocks A and C. However, the arrangement position may exist in an asymmetric block, for example, the second electrode and/or the fourth electrode are only in adjacent blocks of blocks A and B.

Continuing the above description, except for the number and arrangement position, the first electrode assembly 126 and the third electrode assembly 128 provide independent modes of the power signal and the control signal from each other, and the second electrode The assembly 1410 and the fourth electrode assembly 1412 provide an independent mode of a power signal and a control signal to each other, and the first electrode assembly 126 or the third electrode assembly 128 receives a power signal and a control signal at the same time. A mixing mode is provided, and a mixing mode of the power signal and the control signal is provided to the second electrode assembly 1410 or the fourth electrode assembly 1412 at the same time.

<Second embodiment>

Reference is made to FIG. 6 , which is a schematic diagram for explaining another embodiment of the female socket of FIG. 3 . In FIG. 6 , the female socket 14 includes the first base body 142 , the second annular body 144 , the fourth annular body 146 , and the second base body 148 of the above-described embodiment. , the second electrode assembly 1410 and the fourth electrode assembly 1412 have other configurations except for the first cover body 16 , the second cover body 18 , and the first protrusion. It has an assembly 1444 and a second protrusion assembly 1464 .

A first base body 142 , a second annular body 144 , a fourth annular body 146 , a second base body 148 , a second electrode assembly 1410 , and a fourth electrode assembly ( 1412) is the same as described above, and thus redundant description is omitted here.

The first cover body 16 is used to shield the floating structure of the second electrode assembly 1410 .

The second cover body 18 is used to shield the floating structure of the fourth electrode assembly 1412 .

A first protrusion assembly 1444 is installed on the outer periphery of the second annular body 144 to install and position the first cover body 16 .

A second protrusion assembly 1464 is provided on the inner periphery of the fourth annular body 146 for installing and positioning the second cover body 18 .

Referring to FIGS. 7a and 7b, which are schematic diagrams for explaining before the coupling of the male plug and the female socket of FIG. 1 of the present invention. Figure 7a is a top view showing before the coupling of the male plug and the female socket of Figure 1 of the present invention is shown, Figure 7b is A-A showing before the coupling of the male plug and the female socket of Figure 7a of the present invention A cross-sectional side view is shown. 7A and 7B may be used to aid in the description of the above-described embodiment. When the male plug 12 is about to be coupled toward the female socket 14 , the third annular body 124 is inserted between the second annular body 144 and the fourth annular body 146 , so that the third electrode assembly Electrically connect the second end 1284 of 128 to the first end 14102 of the second electrode assembly 1410 and connect the second end 1264 of the first electrode assembly 126 to the fourth electrode assembly electrically connected to the first end 14122 of 1412 .

2… 1st circuit board 4... second circuit board
10… Toroidal connector 12… male plug
122… 1st annular body 1222... first home body
1224… 5th home body 124... third annular body
1242… 3rd home 1244... 7th home
126… The first electrode assembly 1262 . . . first end of the first electrode assembly
1264... second end of the first electrode assembly
128… The third electrode assembly 1282 . . . first end of the third electrode assembly
1284… second end of the third electrode assembly
14… female socket 142… first base body
1422… Home 144… second annular body
1442… 2nd home body 1444... first protrusion assembly
146… 4th annular body 1462... 4th home
1464… The second protrusion assembly 148 . second base body
1482… Home body 1410… second electrode assembly
14102… The first end 14104 of the second electrode assembly. second end of the second electrode assembly
1412… The fourth electrode assembly 14122 . first end of the fourth electrode assembly
14124… The second stage 16 of the fourth electrode assembly... first cover body
18… 2nd cover body O... node
θ1, θ… Minimum angle A, B, C, D… block

Claims (10)

A toroidal connector applied between a first circuit board and a second circuit board, comprising:
a male plug for connection with the first circuit board and a female socket for connection with the second circuit board;
The male plug has a first annular body, a third annular body superimposed on the first annular body, a first electrode assembly, and a third electrode assembly, for installing a first end of the first electrode assembly A first groove is formed on the inner periphery of the first annular body, and a third groove is formed on the inner periphery of the third annular body for installing the second end of the first electrode assembly. formed, a fifth groove is formed on the outer periphery of the first annular body for installing the first end of the third electrode assembly, and for installing the second end of the third electrode assembly A seventh groove is formed on the outer periphery of the third annular body,
The female socket has a first base body, a second annular body, a fourth annular body, a second base body, a second electrode assembly, and a fourth electrode assembly, and includes a center point of the female socket. arranged with the second base body, the fourth annular body, the second annular body, and the first base body, respectively, outwardly from the second base body, between the first base body and the second annular body An electrode assembly is installed, the fourth electrode assembly is installed between the fourth annular body and the second base body, and the seventh electrode assembly is installed in the second annular body to install the first end of the second electrode assembly. A second groove corresponding to the groove is formed, a fourth groove is formed in the fourth annular body to install the first end of the fourth electrode assembly, and a fourth groove is formed corresponding to the third groove, the second electrode assembly and At least one of the fourth electrode assemblies has a floating structure,
When the third annular body is inserted between the second annular body and the fourth annular body, the male plug and the female socket are coupled, and the second end of the third electrode assembly is connected to the second end of the second electrode assembly. and electrically connecting a first end to a first end and electrically connecting a second end of the first electrode assembly to a first end of the fourth electrode assembly. According to claim 1,
The floating structure is formed between the first end and the second end of the second electrode assembly,
In addition, the floating structure is formed between the first end and the second end of the fourth electrode assembly,
The toroidal connector, characterized in that the shape of the floating structure is approximately S-shaped. According to claim 1,
The second electrode assembly is composed of a plurality of second electrodes,
The range of the minimum angle sandwiched between the plurality of second electrodes from the center point of the second annular body corresponds to the size of the solder at which the second end of the second electrode assembly is soldered to the second circuit board. characterized by a toroidal connector. According to claim 1,
The fourth electrode assembly is composed of a plurality of fourth electrodes,
The range of the minimum angle sandwiched between the plurality of fourth electrodes from the center point of the fourth annular body corresponds to the size of the solder at which the second end of the fourth electrode assembly is soldered to the second circuit board. characterized by a toroidal connector. According to claim 1,
The number of the second electrode assemblies of the second annular body is not less than the number of the fourth electrode assemblies of the fourth annular body,
The second electrode assembly is composed of a plurality of second electrodes,
The fourth electrode assembly is composed of a plurality of fourth electrodes,
An arrangement position of the plurality of second electrodes and an arrangement position of the plurality of fourth electrodes are formed symmetrically or asymmetrically. According to claim 1,
The first electrode assembly and the third electrode assembly provide an independent mode of a power signal and a control signal from each other,
wherein the second electrode assembly and the fourth electrode assembly provide independent modes of the power signal and the control signal from each other. According to claim 1,
providing a mixing mode of a power signal and a control signal at the same time for the first electrode assembly or the third electrode assembly;
wherein the second electrode assembly or the fourth electrode assembly simultaneously provides a mixing mode of the power signal and the control signal. According to claim 1,
wherein the first electrode assembly, the third electrode assembly, the second electrode assembly and the fourth electrode assembly respectively supply a power signal or a control signal. A male plug of an annular connector having a first annular body, a third annular body, a first electrode assembly, and a third electrode assembly, the male plug comprising:
The first annular body has a first groove formed on its inner periphery, and a fifth groove formed on its outer periphery,
the third annular body is stacked on the first annular body, a third groove body is formed on its inner periphery, and a seventh groove body is formed on its outer periphery;
In the first electrode assembly, a first end thereof is installed in the first groove body, and a second end thereof is installed in the third groove body;
The third electrode assembly has a first end installed in the fifth groove body and a second end of the third electrode assembly is installed in the seventh groove body. A female socket of an annular connector having a first base body, a second annular body, a fourth annular body, a second base body, a second electrode assembly, and a fourth electrode assembly, the female socket comprising:
A second groove body is formed in the second annular body installed in the first base body,
A fourth groove is formed in the fourth annular body installed in the second annular body,
The second base body is installed in the fourth annular body,
A first end of the second electrode assembly installed between the first base body and the second annular body is installed in the second groove body,
The second electrode assembly has a floating structure,
A first end of the fourth electrode assembly installed between the fourth annular body and the second base body is installed in the fourth groove body,
The fourth electrode assembly has a floating structure,
and the second base body, the fourth annular body, the second annular body, and the first base body are respectively arranged outward from the center point of the female socket.

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