CN216750540U - Double-port connector with function of preventing false touch - Google Patents

Abstract

The utility model relates to the technical field of circuit connectors, in particular to a double-port connector with a function of preventing false touch.A first conductive structure electrically connected with a circuit connecting port is arranged in a connecting female seat, the inner end of the first conductive structure is connected with a second conductive structure, the second conductive structure is electrically connected to the tail end of the connecting female seat, and the connecting female seat is provided with a power-off structure for driving the first conductive structure and the second conductive structure to be disconnected; the second conductive structure is connected with the first conductive structure, when power failure is needed, a power failure button is pressed, and the power failure button drives the power failure block to slide in the connecting female seat through the transmission structure, so that the first conductive structure and the second conductive structure are separated from each other, and power failure is realized; in order to prevent that the mistake from touching the outage button, carry out the locking through the first locking structure of plug to transmission structure, need extract first locking structure, otherwise the outage button that presses is invalid to realize preventing the effect that the mistake touched, can not influence the normal electricity of public seat and connection female seat and be connected.

Description

Double-port connector with function of preventing false touch

Technical Field

The utility model relates to the technical field of circuit connectors, in particular to a double-port connector with a false touch prevention function.

Background

The circuit connector comprises a male seat and a female seat, and the electric connection is realized by the way of connecting the male seat and the female seat.

In some electrical connectors, when an emergency situation is handled, a circuit breaking device is disposed on the male socket or the female socket, so that the circuit connection between the male socket and the female socket is in a disconnected state.

The design structure of this kind of button causes the mistake easily and touches for the phenomenon that breaks off appears easily in the button of colliding with carelessly under the abnormal condition, influences the normal electricity of public seat and female seat and connects.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a double-port connector with a false touch prevention function aiming at the defects in the prior art.

In order to realize the purpose, the technical scheme of the utility model is as follows:

the utility model provides a double-port connector with prevent mistake and touch function, including connecting female seat, it is provided with two circuit connectors to connect female seat one end, be provided with the first conductive structure of being connected with circuit connector electricity in the female seat of connection, first conductive structure the inner is connected with second conductive structure, second conductive structure electricity is connected to the end of connecting female seat, the female seat of connection is provided with the outage structure that drives first conductive structure and second conductive structure and break and connect, the outage structure is including setting up the outage button on connecting female seat lateral wall, first conductive structure one end is connected with the outage piece, outage button the inner is connected with the gliding transmission structure of outage piece that drives and is connected with first conductive structure, still the plug has the first structure of locking that the transmission structure carries out the locking in the female seat of connection.

Further: the female seat of connection is interior to be shaped into has the transmission chamber that is used for installing transmission structure, and transmission structure includes the drive slider with outage button sliding fit and perpendicular to outage button, and the direction of motion of drive slider is opposite with the direction of motion of outage button, and the outage piece is connected with the drive slider.

Further: the transmission cavity comprises a vertically arranged button slot for slidably mounting the power-off button and a first slider slot for slidably mounting the driving slider, and one end of the first slider slot is communicated with a second slider slot for sliding the power-off block.

Further: the lateral wall shaping of outage button and the laminating of drive slider has first inclined plane, and the shaping of drive slider has the second inclined plane with first inclined plane sliding fit.

And further: the second conductive structure is fixed in the transmission cavity, conductive blocks are formed on the side wall of the first conductive structure and the side wall of the second conductive structure, the conductive blocks of the first conductive structure are connected with the power-off block, a driving spring for driving the first conductive structure to be close to the second conductive structure is arranged on one side of the first conductive structure, and the power-off block is connected to the outer side wall of the conductive block.

Further: the first locking structure comprises a first locking rod inserted into the driving slider from the connecting female seat and penetrating through the driving slider, and a first locking groove for the first locking rod to insert is coaxially formed in the connecting female seat and the driving slider.

Further: be provided with the second on the outage button and only lock the structure, the second only locks the structure and passes the outage button and insert the second locking pole to button inslot lateral wall including the level, and button inslot lateral wall and outage button shaping respectively have the second that supplies the second locking pole to pass and only lock the groove.

Further: the second locking groove of the power-off button is higher than the second locking groove on the button groove, and a compression spring which enables the power-off button to bounce upwards is arranged between the bottom groove of the button groove and the bottom of the power-off button.

Further: a stop block is arranged in a second locking groove of the power-off button, and a stop ring matched with the stop block is formed at the end part of the second locking rod; the button groove is a stepped groove, the width of the lower half part of the button groove is larger than that of the upper half part, and the width of the lower half part of the power-off button is larger than that of the upper half part.

The utility model has the beneficial effects that: according to the double-port connector with the false touch prevention function, when power is cut off, the power-off button is pressed, and the power-off button drives the power-off block to slide in the connecting female seat through the transmission structure, so that the first conductive structure and the second conductive structure are separated from each other, and power off is realized; in order to prevent that the mistake from touching the outage button, carry out the locking through the first locking structure of plug to transmission structure, need extract first locking structure, otherwise the outage button that presses is invalid to realize preventing the effect that the mistake touched, can not influence the normal electricity of public seat and connection female seat and be connected.

Drawings

Fig. 1 is a schematic structural diagram of a dual port connector.

Fig. 2 is a schematic view of the front view of the dual port connector.

Fig. 3 is a schematic view of the internal structure of the dual port connector.

Fig. 4 is a schematic view of a part of the enlarged structure in fig. 3.

Fig. 5 is a partially enlarged schematic view of fig. 3.

Fig. 6 is a schematic view of another dual port connector.

The reference numerals include:

1-connecting the female seat,

11-circuit connection port, 12-wire, 13-first conductive structure, 14-second conductive structure,

15-conductive block, 16-first compression spring,

2-a transmission structure,

21-power-off button, 22-driving slide block, 23-first inclined plane, 24-second inclined plane, 25-power-off block,

3-a transmission cavity,

31-button groove, 32-first slide groove, 33-second slide groove,

4-a first locking structure,

40-second locking structure, 41-first locking groove, 42-first locking bar, 43-second locking groove, 44-second locking bar, 45-stop block, 46-stop ring, 47-second compression spring.

Detailed Description

The present invention is described in detail below with reference to the attached drawings.

As shown in fig. 1-6, a dual port connector with function of preventing false touch, including connecting female seat 1, connecting female seat 1 one end and being provided with two circuit connectors 11, be provided with the first conductive structure 13 with circuit connector 11 electricity connection in connecting female seat 1, first conductive structure 13 the inner is connected with second conductive structure 14, second conductive structure 14 is connected to the end of connecting female seat 1 through electric wire 12 electricity, connecting female seat 1 is provided with the outage structure that drives first conductive structure 13 and second conductive structure 14 disconnected, the outage structure is including setting up outage button 21 on connecting female seat 1 lateral wall, first conductive structure 13 one end is connected with outage piece 25, outage button 21 the inner is connected with drives the gliding transmission structure 2 of outage piece 25 that is connected with first conductive structure 13, still plug in connecting female seat 1 has the first locking structure 4 that carries out the locking to transmission structure 2.

The male connection seat is in circuit connection through the two circuit connection ports 11 and is transmitted to the first conductive structure 13, the second conductive structure 14 is connected with the first conductive structure 13, when power failure is needed, the power failure button 21 is pressed, the power failure button 21 drives the power failure block 25 to slide in the female connection seat 1 through the transmission structure 2, so that the first conductive structure 13 and the second conductive structure 14 are separated from each other, and power failure is realized; in order to prevent that the mistake from touching outage button 21, carry out the locking through the first locking structure 4 of plug to drive structure 2, need extract first locking structure 4, otherwise the outage button 21 that presses is invalid to realize the effect of preventing the mistake and touching, can not influence the normal electricity of public seat and connection female seat 1 and connect.

Specifically, the method comprises the following steps: a transmission cavity 3 for installing a transmission structure 2 is formed in the connecting female seat 1, the transmission structure 2 comprises a driving slide block 22 which is in sliding fit with the power-off button 21 and is vertical to the power-off button 21, the moving direction of the driving slide block 22 is opposite to that of the power-off button 21, and the power-off block 25 is connected with the driving slide block 22; the transmission cavity 3 comprises a vertically arranged button slot 31 for slidably mounting the power-off button 21 and also comprises a first slider slot 32 for slidably mounting the driving slider 22, and one end of the first slider slot 32 is communicated with a second slider slot 33 for the power-off block 25 to slide; the side wall of the power-off button 21 attached to the driving slider 22 is formed with a first inclined surface 23, and the driving slider 22 is formed with a second inclined surface 24 in sliding fit with the first inclined surface 23.

The power-off button 21 is pressed, the power-off button 21 slides downwards along the button groove 31, so that the first inclined surface 23 of the side wall is in sliding fit with the second inclined surface 24 of the driving slider 22, the driving slider 22 horizontally slides towards the direction close to the first conductive structure 13 along the first slider groove 32, the power-off block 25 connected with the driving slider 22 drives the first conductive structure 13 to perform sliding motion away from the second conductive structure 14, the first conductive structure 13 and the second conductive structure 14 which are electrically connected with each other are separated, and power-off is realized.

Preferably, the following components: the second conductive structure 14 is fixed in the transmission cavity 3, conductive blocks 15 are formed on the side walls of the first conductive structure 13 and the second conductive structure 14, a driving spring for driving the first conductive structure 13 to approach the second conductive structure 14 is arranged on one side of the first conductive structure 13, and the power-off block 25 is connected to the outer side wall of the conductive block 15 of the first conductive structure 13; when the power-off button 21 is not pressed, the driving spring is the first compression spring 16, which drives the first conductive structure 13 to pop out to the second conductive structure 14 to keep electrical connection; when the power-off button 21 is pressed, the transmission structure 2 drives the conductive block 15 connected with the power-off block 25 to be separated from the second conductive structure 14, so that power-off is realized; when the power-off button 21 is retracted to the initial position, the first compression spring 16 will retract the conductive block 15 into contact with the conductive block 15 of the second conductive structure 14 to make electrical connection, and the power-off block 25 and the driving slider 22 will also slide along the first slider groove 32 and the second slider groove 33 to the initial position.

The first locking structure 4 comprises a first locking bar 42 inserted into the driving slider 22 from the connecting female socket 1 and penetrating through the driving slider 22, and a first locking groove 41 for inserting the first locking bar 42 is coaxially formed on the connecting female socket 1 and the driving slider 22; in order to prevent the occurrence of accidental touch caused by randomly pressing the power-off button 21, at the initial position, the first locking groove 41 of the female seat 1 and the first locking groove 41 of the driving slider 22 are coaxially aligned, at this time, the first locking bar 42 is inserted into the aligned first locking groove 41, the first locking bar 42 penetrates through the driving slider 22 and the side wall of the transmission cavity 3 to lock the driving slider 22, and when the power-off button 21 is pressed, the driving slider 22 cannot slide, so that the first conductive structure 13 cannot be controlled to be separated from the second conductive structure 14, and therefore, the normal electrical connection between the male seat and the female seat can be ensured, and the power is supplied in real time.

In order to keep the power-off function after the power-off button 21 is pressed, a second locking structure 40 is arranged on the power-off button 21, the second locking structure 40 comprises a second locking rod 44 horizontally penetrating through the power-off button 21 and inserted into the inner side wall of the button groove 31, and a second locking groove 43 for the second locking rod 44 to penetrate through is respectively formed on the inner side wall of the button groove 31 and the power-off button 21.

After the power-off button 21 is pressed, the power-off button 21 slides downwards along the button slot 31 until the second locking slot 43 on the power-off button 21 is aligned with the second locking slot 43 on the button slot 31, and the second locking bar 44 inserted into the power-off button 21 extends into the second locking slot 43 of the button slot 31, so that the power-off button 21 is locked and the pressed state is kept; the transmission structure 2, now connected to the power-off button 21, maintains the first and second conductive structures 13 and 14 in a separated power-off state.

The second locking groove 43 of the power cut button 21 is higher than the second locking groove 43 of the button groove 31, and a second compression spring 47 for bouncing the power cut button 21 upwards is arranged between the bottom groove of the button groove 31 and the bottom of the power cut button 21. When the power failure needs to be recovered, the second locking bar 44 is pulled out of the second locking groove 43 of the button groove 31, the power failure button 21 slides upwards from the button groove 31 by the elastic force of the second compression spring 47, and the first conductive structure 13 is rebounded by the elastic force of the first compression spring 16 to be electrically connected with the second conductive structure 14, so that the normal electrical connection is recovered.

Preferably, a stop block 45 is arranged in the second locking groove 43 of the power-off button 21, a stop ring 46 matched with the stop block 45 is formed at the end of the second locking rod 44, and the stop ring 46 can prevent the second locking rod 44 from being separated from the power-off button 21 and can be stored.

In order to prevent the power-off button 21 from being separated from the button groove 31 when sliding upwards, the button groove 31 is a stepped groove, the width of the lower half part of the button groove 31 is larger than that of the upper half part, the width of the lower half part of the power-off button 21 is larger than that of the upper half part, when sliding upwards, the button groove 31 is formed with steps, and the side wall of the power-off button 21 is also formed with matched steps, so that when the power-off button 21 slides upwards to be in contact with the steps of the button groove 31, the power-off button 21 cannot continuously slide upwards and stays at the step position, and the power-off button 21 is prevented from being separated from the button groove 31.

In conclusion, the present invention has the above-mentioned excellent characteristics, so that it can be used to enhance the performance of the prior art and has practicability, and becomes a product with practical value.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, the present invention should not be limited by the description of the present invention, which should be interpreted as a limitation.

Claims (9)

1. The utility model provides a double-port connector with prevent mistake and touch function, is provided with two circuit connectors, its characterized in that including connecting female seat, connecting female seat one end: the utility model discloses a female seat of circuit, including female seat, be provided with the first conductive structure who is connected with circuit connector electricity in the female seat of connection, first conductive structure the inner is connected with the second conductive structure, second conductive structure electricity is connected to the end of connecting female seat, it is provided with the outage structure that drives the first conductive structure and the second conductive structure is disconnected to connect female seat, the outage structure is including setting up the outage button on connecting female seat lateral wall, first conductive structure one end is connected with the outage piece, outage button the inner is connected with and drives the gliding transmission structure of outage piece that is connected with first conductive structure, it has the first locking structure that carries out the locking to transmission structure still to plug in the female seat of connection.

2. The dual port connector with false touch prevention function according to claim 1, wherein: the female seat of connection is interior the shaping has the transmission chamber that is used for installing transmission structure, and transmission structure includes with outage button sliding fit and perpendicular to outage button's drive slider, and the direction of motion of drive slider is opposite with the direction of motion of outage button, and the outage piece is connected with drive slider.

3. The dual port connector with false touch prevention function according to claim 2, wherein: the transmission cavity comprises a vertically arranged button slot for slidably mounting the power-off button and a first slider slot for slidably mounting the driving slider, and one end of the first slider slot is communicated with a second slider slot for sliding the power-off block.

4. The dual port connector with false touch prevention function according to claim 3, wherein: the lateral wall shaping of outage button and the laminating of drive slider has first inclined plane, and the shaping of drive slider has the second inclined plane with first inclined plane sliding fit.

5. The dual port connector with false touch prevention function according to claim 2, wherein: the second conductive structure is fixed in the transmission cavity, conductive blocks are formed on the side wall of the first conductive structure and the side wall of the second conductive structure, the conductive blocks of the first conductive structure are connected with the power-off block, a driving spring for driving the first conductive structure to be close to the second conductive structure is arranged on one side of the first conductive structure, and the power-off block is connected to the outer side wall of the conductive block.

6. The dual-port connector with false touch prevention function according to claim 4, wherein: the first locking structure comprises a first locking rod inserted into the driving slider from the connecting female seat and penetrating through the driving slider, and a first locking groove for the first locking rod to insert is coaxially formed in the connecting female seat and the driving slider.

7. The dual port connector with false touch prevention function according to claim 6, wherein: be provided with the second locking structure on the outage button, the second locking structure includes that the level passes the outage button and inserts the second locking pole to the button inslot lateral wall, and button inslot lateral wall and outage button shaping respectively have the second locking groove that supplies the second locking pole to pass.

8. The dual port connector with false touch prevention function according to claim 7, wherein: the second locking groove of the power-off button is higher than the second locking groove on the button groove, and a compression spring which enables the power-off button to bounce upwards is arranged between the bottom groove of the button groove and the bottom of the power-off button.

9. The dual port connector with false touch prevention function of claim 8, wherein: a stop block is arranged in a second locking groove of the power-off button, and a stop ring matched with the stop block is formed at the end part of the second locking rod; the button groove is a stepped groove, the width of the lower half part of the button groove is larger than that of the upper half part, and the width of the lower half part of the power-off button is larger than that of the upper half part.

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