CN113036497B - Terminal insulation isolation plate and bridging structure for electric connector - Google Patents

Abstract

The invention provides a terminal insulation isolation plate and a bridging structure for an electric connector, wherein a wire groove is arranged on the terminal insulation isolation plate, one end of the terminal insulation isolation plate is of a step structure, the appearance design can be carried out according to the structural characteristics of the used electric connector, and the bridging is of a conductive metal sheet or metal strip structure and is arranged at a wire installation part of the used electric connector. The invention can solve the problem of difficult installation of the high-density lead on the small and miniature electric connector, not only can ensure that the installation of the high-density lead on the electric connector is convenient and safe, but also provides a simple solution for the installation of the lead of double-point single-wire, and the use amount of the lead can be reduced by 50 percent compared with the commonly adopted lead of double-point double-wire under the condition of the same reliability.

Description

Terminal insulation isolation plate and bridging structure for electric connector

Technical Field

The invention relates to the technical field of electric connector design, in particular to a terminal insulation isolation plate and a bridging structure which can be used for an electric connector.

Background

The existing small and micro electric connectors are all designed to be of a mutual exposed structure, and have two technical defects.

On one hand, when the welding device is used, the wire installation parts are arranged densely (the distance is 0.635-1.27 mm), the outer diameter of the installed wires is often equal to or slightly larger than the arrangement distance of the wire installation parts and slightly smaller than the arrangement distance of the wire installation parts, a heat-shrinkable sleeve is required to be adopted for isolation protection after welding, no operation space exists, the operation is difficult, and the installation points are often damaged due to extrusion of the heat-shrinkable sleeve.

On the other hand, the arrangement is made by installing the wire designed as the double-point double-wire (namely, one signal is transmitted by two terminals and one wire), and the double-point double-wire (namely, one signal is transmitted by two terminals and two wires) is largely used in the prior art to ensure the reliability of connection, so that the system volume, weight and cost are greatly wasted.

Disclosure of Invention

The present invention provides a terminal insulation isolation board and a bridge for an electric connector, which can effectively solve the problems described in the background art, so that the installation of a small and miniature electric connector becomes convenient and safe, and can realize the wire installation of a double-point single wire, wherein the double-point single wire is compared with the existing double-point double wire, the reliability is not lost, but the wire usage amount can be reduced by 50%.

The invention discloses a terminal insulation isolation board and bridging structure for electric connector, which comprises: the terminal insulation isolation plate comprises a wire groove and a step, the wire groove is arranged on the step, and the appearance structure of the terminal insulation isolation plate can be designed according to the structural characteristics of the used electric connector;

and a wire is arranged in the wire slot and is connected with terminals of the electric connector, two adjacent terminals are connected through a bridge, one terminal of the two adjacent terminals is connected with the wire, and the bridge is connected with a conductive metal sheet or metal strip.

Preferably, a plurality of wire grooves are arranged on the terminal insulating isolation plate, and the width, depth, length and number of the wire grooves can be correspondingly arranged according to the size and arrangement form of the terminals on the used electric connector.

Preferably, one end of the terminal insulating and isolating plate is a stepped structure, and the terminal insulating and isolating plate can be correspondingly arranged according to the structure and the arrangement form of the wire mounting part corresponding to the terminal on the used electric connector.

Preferably, the bridges are conductive metal sheets or strips having an appearance and size compatible with the structure of the terminal insulating spacer and the wire mounting portion of the electrical connector to be used.

Preferably, the bridging structure may be in the form of a "Π" or "Ω" and is disposed between wire mounting portions of adjacent terminals on an electrical connector, one of the terminals being connected to a wire.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of the structure of the present invention.

Fig. 2 is a schematic diagram of a typical application of the present invention.

Fig. 3 is a schematic diagram of a wire mounting point design of a typical prior art electrical connector.

Fig. 4 is a schematic view of the protection device of the present invention.

Fig. 5 is a schematic structural view of the fastening device of the present invention.

Fig. 6 is a schematic structural view of the locking device of the present invention.

FIG. 7 is an enlarged view of the part A of the present invention 6.

FIG. 8 is a side view of the locking device of FIG. 6 according to the present invention;

FIG. 9 is a schematic view of a stop collar according to the present invention.

In the figure: 1. a terminal insulating separator; 2. an electrical connector; 3. a wire slot; 4. a step; 5. a wire mounting point; 6. a wire; 7 a lead mounting part; 8. encapsulating the filling material; 9. bridging; 10. a microcontroller; 11. a current transformer; 12. a resistor; 13 terminals; 14. a second threaded hole; 601. a first rotating shaft; 602. a limiting ring; 603. a first clamping block; 604. a second fixture block; 605. a first fixed block; 6021. an inner wheel; 6022. adjusting the groove; 6023. a gear lever; 6024. an outer ring; 6025. installing a groove; 6026. a second rotating shaft; 6027. a pawl; 6031. a first L-shaped bar; 6032. a first swash block; 6033. a second L-shaped bar; 6034. a first sawtooth block; 6041. a third L-shaped bar; 6042; a second swash block; 6043. a fourth L-shaped bar; 6044. a second sawtooth block; 701. an installation table; 702. a drive motor; 703. a threaded rod; 704. a threaded sleeve; 705. a first adjusting lever; 706. a second adjusting lever; 707. a third adjusting rod; 708. a compression block; 710. a sliding groove.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it should be understood that they are presented herein only to illustrate and explain the present invention and not to limit the present invention.

Technical solutions and technical features between various embodiments can be combined with each other, but must be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not be within the protection scope of the present invention.

Example 1:

referring to fig. 1-3, in one embodiment of the present invention, a terminal insulating spacer and bridging structure for an electrical connector includes: the terminal insulation isolation plate 1 comprises a wire groove 3 and a step 4, the wire groove 3 is arranged on the step 4, and the appearance structure of the terminal insulation isolation plate 1 can be designed according to the structural characteristics of the used electric connector 2;

a wire 6 is installed in the wire slot 3, the wire 6 is connected with terminals 13 of the electrical connector 2, two adjacent terminals 13 are connected through a bridge 9, one terminal 13 of the two adjacent terminals 13 is connected with the wire 6, and the bridge 9 is a conductive metal sheet or metal strip.

Preferably, a plurality of wire slots 3 are arranged on the terminal insulating and isolating plate 1, and the width, depth, length and number of the wire slots 3 can be correspondingly set according to the size and arrangement form of the terminals 13 on the used electric connector 2.

The working principle and the beneficial effects of the technical scheme are as follows: install wire 6 on electric connector 2 and realize the insulating isolation of natural physics of wire 6 in the wire casing 3 on terminal insulation division board 1, the insulating isolation of natural physics of wire 6 has been realized, need not to use heat shrinkable tube behind the wire 6 installation, make operation and detection all very convenient and safe and reliable, it must adopt heat shrinkable tube isolation protection but do not have operating space to have solved after the wire welding, the problem of operation difficulty and often lead to the mounting point to damage because of heat shrinkable tube's extrusion, and connect terminal 13 that wire 6 is connected through bridging 9, realize that signal is transmitted by two terminals 13 and a wire 6 all the way, the system volume has been reduced, weight and cost.

Example 2:

referring to fig. 1-3, in the embodiment 1, one end of the terminal insulating spacer 1 is in a step-like structure, and all the steps can be arranged according to the structure and arrangement of the wire mounting portion 7 of the terminal of the electrical connector to be used.

The working principle and the beneficial effects of the technical scheme are as follows: one end of the terminal insulating isolation plate 1 is arranged in a step shape, the step shape is the same as the distribution of the wire mounting points 5 on the terminals on the used electric connector 2, the distance between the mounting parts of the terminals 13 in different rows is pulled, the natural physical insulating isolation of the terminals 13 in different rows is formed, and the wires 6 are effectively isolated.

Example 3:

referring to the attached figures 1-3, on the basis of the embodiment 1 or 2, the method comprises the following steps: the bridges 9 are conductive metal sheets or strips having an appearance and size compatible with the structures of the terminal insulating spacer 1 and the wire mounting portion 7 of the electrical connector 2 to be used.

The terminal insulating and isolating plate 1 is made of a non-conductive material and meets the requirements of the use environment of the used electric connector 2.

The working principle and the beneficial effects of the technical scheme are as follows: the bridge 9 is a conductive metal sheet or strip to connect the terminals 13, the terminal insulating isolation plate 1 is made of a non-conductive material to achieve its insulating function, and the non-conductive material used for the terminal insulating isolation plate 1 meets the requirements of the use environment of the used electrical connector 2 (such as temperature, humidity, corrosion, radiation, life, etc.) to ensure that the used electrical connector 2 can normally work.

Example 4:

on the basis of any one of embodiments 1-3, the method comprises the following steps: the bridges 9 are made of metal sheets or strips, and have a "pi" or "Ω" structure and are adapted to the structure of the soldering portions of the terminals 13 of the insulating isolation board 1 on the used electrical connector 2.

The working principle and the beneficial effects of the technical scheme are as follows: the bridging link 9 is arranged between the adjacent wire installation parts 7 on the electric connector 2 and is installed together with the wire 6, the termination of the adjacent terminals is realized, the space is not occupied, the operation is simple, the wire installation of double-point single-wire is implemented, compared with the traditional double-point double-wire, the reliability is not lost, but the wire use is saved by 1/2, and the volume, the weight and the cost of the system are obviously reduced.

Example 5

On the basis of any one of embodiments 1 to 4, the method comprises the following steps: the electric connector 2 is further provided with a filling sealing shell 8, and the filling sealing shell 8 is sleeved outside the insulating isolation plate 1.

The working principle and the beneficial effects of the technical scheme are as follows: by arranging the potting shell 8, the wires 6 and the bridges 9 in the electric connector 2 can be protected, and the stability of the device is prevented from being damaged by external collision.

Example 6

On the basis of embodiment 5, as shown in fig. 4, a protection device is further disposed on the electrical connector, and the protection device includes:

a microcontroller 10, said microcontroller 10 being disposed on said electrical connector;

a disconnect switch disposed on the electrical connector;

the current transformer 11 is arranged on the electric connector and used for generating an induced current with the current of an original circuit, and the original circuit is a circuit connected to the connector;

a resistor 12, the resistor 12 being connected in parallel with the current transformer 11 for stabilizing an induced current;

the first current detection device is arranged on the electric connector and used for detecting the current of the original circuit;

second current detection means provided on the resistor 12 for detecting a current flowing through the resistor 12;

the current frequency detection device is arranged on the electric connector and is used for detecting the frequency of an original circuit;

the microcontroller is electrically connected with the current transformer 11, the resistor 12, the first current detection device, the second current detection device, the current frequency detection device and the circuit breaker, and controls the circuit breaker to work based on the first current detection device, the second current detection device and the current frequency detection value, and the method comprises the following steps:

step 1, calculating an equivalent current I passing through a current transformer 11 according to detection values of a first current detection device, a second current detection device and a current frequency detection device and a formula (1);

wherein R is ₀ Is the coil resistance of the current transformer 11, N is the number of coil turns of the current transformer 11, R ₁ The resistance of the resistor 12, the mutual inductance of the M current transformer 11, ω is the detection value of the current frequency detection means, I ₁ Is a detected value of the first current detecting means, I ₂ Is the detection value of the second current detection device;

step 2, calculating a stability coefficient A of the current of the original circuit according to a formula (2);

wherein, C ₀ Is the capacitance of the current transformer 11;

and 3, comparing the stability coefficient of the original circuit current calculated in the step 2 with a preset value by the microcontroller, and controlling a circuit breaker to cut off the original circuit by the microcontroller 10 when the stability coefficient of the original circuit current calculated in the step 2 is greater than the preset value.

The stability factor of the current reflects the rate of change of the original circuit current.

The working principle and the beneficial effects of the technical scheme are as follows: the current transformer 11 can induce the current of the original circuit to generate an induced current, the equivalent current passing through the current transformer 11 is calculated according to the detection values of the first current detection device, the second current detection device and the current frequency detection device and a formula (1), then the stability coefficient of the current of the original circuit is calculated according to the calculation result of the step 1 and a formula (2), finally, the microcontroller compares the stability coefficient of the current of the original circuit calculated in the step 2 with the preset value, when the stability coefficient of the current of the original circuit calculated in the step 2 is larger than the preset value, the circuit current is abnormal, and the microcontroller controls the circuit breaker to cut off the original circuit.

Example 7

On the basis of embodiment 5, as shown in fig. 5, a fastening device is further disposed on the electrical connector 2, and the fastening device includes:

the mounting table 701, the said mounting table 701 is fixedly connected to the said electric connector 2;

the driving motor 702 is fixedly arranged on the mounting table 701;

one end of the threaded rod 703 is fixedly connected to the output end of the driving motor 702, and the other end of the threaded rod 703 is rotatably connected with the mounting table 701 through a bearing;

a threaded sleeve 704, said threaded sleeve 704 being threadedly connected to said threaded rod 703;

an adjustment assembly, the adjustment assembly comprising:

a first adjusting rod 705, wherein the first adjusting rod 705 is arranged in the mounting table 701, and one end of the first adjusting rod 705 is rotatably connected with the threaded sleeve 704 through a rotating shaft;

one end of the second adjusting rod 706 is rotatably connected with the other end of the first adjusting rod 705 through a rotating shaft;

one end of the third adjusting rod 707 is fixedly connected with the other end of the second adjusting rod 706, and the third adjusting rod 707 and the second adjusting rod 706 are vertically arranged;

the sliding groove 710 is arranged in the mounting table 701, and the other end of the third adjusting rod 707 extends into the sliding groove 710;

a pressing block 708, wherein the pressing block 708 is arranged in the sliding groove 710, the pressing block 708 is fixedly connected with the other end of the third adjusting rod 707, and the pressing block 708 can be pressed against the terminal insulating isolation plate 1;

the adjustment assemblies are arranged in two groups, symmetrically arranged about the threaded rod 703.

Above-mentioned technical scheme's theory of operation and beneficial effect do, insert electric connector 2 after terminal insulation division board 1, start driving motor 702, driving motor 702 drives threaded rod 703 and rotates, threaded rod 703 drives threaded sleeve 704 and removes, threaded sleeve 704 drives first regulation pole 705, second regulation pole 706, the motion of third regulation pole 707, third regulation pole 707 drives compact heap 708 and compresses tightly terminal insulation division board 1, keep apart insulation board 1 and is fixed in electric connector 2, avoid terminal insulation division board 1 to move, influence the normal work of circuit.

Example 8

On the basis of embodiment 5, as shown in the figure, a plurality of locking devices spaced back and forth are further disposed in the electrical connector 2, and the locking devices include: locking assemblies corresponding up and down;

the locking assembly includes:

the terminal insulation isolation plate 1 is arranged in one side close to the electric connector 2, and two first fixing blocks 605 are arranged at intervals in the front and the back;

two ends of the first rotating shaft 601 are rotatably connected to the two first fixing blocks 605 through bearings, and a second threaded hole 14 is axially formed in the end of the first rotating shaft 601;

the limiting ring 602 is fixedly connected to the first fixing block 605;

a first latch 603, where the first latch 603 is fixedly connected to the first rotating shaft 601;

and a second latch 604, wherein the second latch 604 is fixedly connected to the terminal insulating spacer 1.

Preferably, the stop collar 602 includes:

the inner wheel 6021 is fixedly connected with a bolt, and the inner wheel 6021 is in threaded connection with the second threaded hole 14 on the first rotating shaft 601 through the bolt;

an adjustment groove 6022, the adjustment groove 6022 being provided on the inner wheel 6021;

a plurality of gear rods 6023, wherein the gear rods 6023 are fixedly arranged on the circumference of the inner wheel 6021;

an outer ring 6024, the outer ring 6024 fixedly attached to the first fixed block 605;

a plurality of mounting grooves 6025, the mounting grooves 6025 disposed within the outer ring 6024;

a second rotating shaft 6026 rotatably coupled within the mounting recess 6025;

a pawl 6027, one end of the pawl 6027 is fixedly connected with the second rotating shaft 6026, and the other end of the pawl 6027 extends out of the mounting groove 6025.

Preferably, the first latch 603 includes:

a first L-shaped rod 6031, an upper end of a vertical section of the first L-shaped rod 6031 is fixedly connected with the first rotating shaft 601;

the first inclined blocks 6032 of the two locking assemblies are fixedly arranged on the sides, close to each other, of the horizontal sections of the first L-shaped rods 6031;

a second L-shaped rod 6033, the vertical end of the second L-shaped rod 6033 is fixedly connected to the horizontal section of the first L-shaped rod 6031;

the first sawtooth block 6034 is fixedly arranged on the horizontal section of the second L-shaped rod 6033;

the second latch 604 includes:

a third L-shaped bar 6041, a vertical section of the third L-shaped bar 6041 being fixedly disposed on the first potting enclosure 301;

the second inclined block 6042 is fixedly arranged on one side, close to the first inclined block 6032, of the horizontal section of the third L-shaped rod 6041, and the first inclined block 6032 and the second inclined block 6042 can be buckled with each other;

a fourth L-shaped bar 6043, a vertical section of the fourth L-shaped bar 6043 being fixedly connected to the third L-shaped bar 6041;

the second sawtooth block 6044 is fixedly arranged on one side of the horizontal section of the third L-shaped rod 6041 close to the first sawtooth block 6034, and the first sawtooth block 6034 and the second sawtooth block 6044 can be mutually buckled.

The working principle and the beneficial effects of the technical scheme are as follows: when the terminal insulating isolation plate 1 is damaged and needs to be replaced, the inner wheel 6021 is rotated through the adjusting groove 6022, the inner wheel 6021 is rotated out of the second threaded hole 14, the baffle rod 6023 on the inner wheel 6021 is not in contact with the pawl 6027, at this time, the first rotating shaft 601 can rotate, the first rotating shaft 601 drives the first clamping block 603 to rotate, the first inclined block 6032 on the first clamping block 603 is not in matched connection with the second inclined block 6042 on the second clamping block 604, the first sawtooth block 6034 is not in matched connection with the second sawtooth block 6044, so that the terminal insulating isolation plate 1 can be taken out of the first encapsulating shell 301, a new terminal insulating isolation plate 1 is replaced, the inner wheel 6021 is rotated reversely, the bolt on the inner wheel 6021 is screwed into the threaded hole, the baffle rod 6023 on the inner wheel 6021 is in contact with the pawl 6027 again, the pawl 6027 limits the first rotating shaft 601 from rotating, and thus realizing the replacement of the terminal insulating isolation plate 1, and the device can replace the terminal insulating isolation plate 1 conveniently and save resources once again after the terminal insulating isolation plate 1 is damaged.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (5)

1. A terminal insulating spacer and bridging structure for use in an electrical connector comprising: the terminal insulation isolation plate (1), the terminal insulation isolation plate (1) comprises a wire groove (3) and a step (4), the wire groove (3) is arranged on the step (4), and the appearance structure of the terminal insulation isolation plate (1) is designed according to the structural characteristics of the used electric connector (2);

a wire (6) is arranged in the wire slot (3), the wire (6) is connected with terminals (13) of the electric connector (2), two adjacent terminals (13) are connected through a bridge (9), one terminal (13) of the two adjacent terminals (13) is connected with the wire (6), and the bridge (9) is a conductive metal sheet or metal strip;

still set up fastener on electric connector (2), fastener includes:

the mounting table (701), the said mounting table (701) is connected fixedly to the said electric connector (2);

the driving motor (702), the said driving motor (702) is fixedly set up on the said mounting table (701);

one end of the threaded rod (703) is fixedly connected to the output end of the driving motor (702), and the other end of the threaded rod (703) is rotatably connected with the mounting table (701) through a bearing;

a threaded sleeve (704), the threaded sleeve (704) being threadedly connected with the threaded rod (703);

an adjustment assembly, the adjustment assembly comprising:

the first adjusting rod (705) is arranged in the mounting table (701), and one end of the first adjusting rod (705) is rotatably connected with the threaded sleeve (704) through a rotating shaft;

one end of the second adjusting rod (706) is rotatably connected with the other end of the first adjusting rod (705) through a rotating shaft;

one end of the third adjusting rod (707) is fixedly connected with the other end of the second adjusting rod (706), and the third adjusting rod (707) and the second adjusting rod (706) are vertically arranged;

the sliding groove (710) is arranged in the mounting table (701), and the other end of the third adjusting rod (707) extends into the sliding groove (710);

the pressing block (708) is arranged in the sliding groove (710), the pressing block (708) is fixedly connected with the other end of the third adjusting rod (707), and the pressing block (708) is pressed against the terminal insulating isolation plate (1);

the adjusting components are arranged in two groups and are symmetrically arranged relative to the threaded rod (703).

2. A terminal insulating spacer and bridging structure useful in electrical connectors as claimed in claim 1, wherein: the terminal insulating isolation board (1) is provided with a plurality of wire grooves (3), and the width, depth, length and number of the wire grooves (3) are correspondingly set according to the size and arrangement form of terminals (13) on the used electric connector (2).

3. A terminal insulating spacer and bridging structure useful in electrical connectors as claimed in claim 1, wherein: one end of the terminal insulating isolation plate (1) is of a step-shaped structure, and the corresponding arrangement is carried out according to the structure and the arrangement form of the lead installation part (7) corresponding to the terminal (13) on the used electric connector (2).

4. A terminal insulating spacer and bridging structure useful in electrical connectors as claimed in claim 1, wherein: the appearance structure and the size of the bridging link (9) are adapted to the structures of the terminal insulating spacer (1) and the wire mounting portion (7) of the electrical connector (2) to be used.

5. A terminal insulating spacer and bridging structure useful in electrical connectors as claimed in claim 1, wherein: the bridging link (9) is in a structure form of n or omega and is arranged between the lead mounting parts (7) of the adjacent terminals on the electric connector (2).

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