WO2017177353A1 - Data line connector - Google Patents

Abstract

A data line connector, comprising a connector body (101), the connector body (101) being connected to a data line (102), wherein a fixing component (300) for fixing the connection position of the connector body (101) and the data line (102) is arranged at the connection position of the connector body (101) and the data line (102), the fixing component (300) is provided with a locating structure for locating an outlet direction of the data line (102) at a tail part of the fixing component with respect to the connector (101), and the data line (102) penetrates through the tail part of the fixing component (300) and is located by the locating structure. According to the design solution, a locating structure for locating a data line (102) at different outlet directions is arranged at a tail part of a fixing component (300), and the data line (102) may penetrate through the tail part of the fixing component (300) and then is located by the locating structure, such that after a connector of a data line is connected, the data line (102) may be fixed and located at different outlet directions according to requirements. In this way, the interference between equipment and a bracket is avoided according to practical requirements, and space is optimized and saved to the utmost.

Description

Data line connector Technical field

The present invention relates to the field of communication cables, and in particular to a data line connector.

Background technique

Modern effects and audio processing equipment are increasingly using MIDI technology, enabling each effect and audio processing device to communicate with each other, allowing control, synchronization, and data stream transmission. The existing MIDI data line connector is provided with a rotation stop groove, and the direction of the rotation stop notch may be different, which makes the connection wire joint cannot rotate arbitrarily once connected. Due to the flow properties of the musician's performance, the effects and audio processing equipment are required to be as compact as possible and easy to carry. However, the existing MIDI data line is set by the anti-rotation slot at the joint, so that the data line connector cannot be rotated in any direction after being connected, and the outgoing direction of the data line is fixed in a single manner, and the interference between the device and the bracket is caused in the joint portion. Can't save space to the maximum.

Summary of the invention

The technical problem to be solved by the present invention is to provide a new data line connector.

In order to solve the above problems, according to an embodiment of the present invention, a data line connector is provided, including a connector body, the connector body being connected to a data line, wherein: a joint of the connector body and the data line is provided for fixing the connector A fixing member of the connecting portion between the body and the data line, the fixing member is provided with a positioning structure for positioning the outgoing direction of the data line with respect to the tail portion of the joint body, and the data line is disposed from the tail portion of the fixing member and positioned by the positioning structure.

Preferably, the positioning structure comprises an outlet slot in one or more directions disposed on a cross section of the tail of the fixing member, and the data line is received from the tail of the fixing member and received into the outlet slot. This The wire trough is set to make the positioning of the data line more reliable and does not shake at will.

Preferably, the tail edge of the fixing member is provided with an edge protruding in the axial direction, and the positioning structure comprises one or more outlets provided on the side edge of the fixing member, the data line is from the tail of the fixing member Pass out and pass through the outlet provided at the side of the tail of the fixed part. Such a setting structure is simple and convenient to implement.

Preferably, the fixing member further includes a rear cover for closing the tail of the fixing member, the rear cover is disposed at a tail portion of the fixing member, and the rear cover is detachably coupled to a tail portion of the fixing member. The rear cover is set to make the positioning and fixing of the data lines better.

Preferably, the positioning structure includes one or more outlets disposed at a peripheral edge of the back cover, the data lines passing through the tail of the fixing member and passing through the outlet provided at the back cover. This can meet the different space requirements for the notch groove in different directions. Regardless of the direction in which the notch groove is in the direction, the data line can be routed in the required outgoing direction, maximizing the optimization and saving space.

Preferably, the positioning structure comprises an outlet groove disposed in one or more directions on a cross section of the tail portion of the fixing member, and an outlet groove disposed in the one or more directions corresponding to the outlet groove of the tail portion of the fixing member on the back cover; When the rear cover is closed, the outlet groove provided at the tail of the fixing member and the outlet groove provided on the rear cover form a receiving cavity, and the data line passes through the tail portion of the fixing member and is fixed by being accommodated in the receiving cavity. This arrangement makes the fixing and positioning of the data line more stable and stable, and can buffer the pulling force to prevent the wire and the MIDI plug soldering part from falling off due to the large pulling force.

Preferably, the rear cover and the tail of the fixing member are connected by a connecting member. The connection is reliable through the connection, the connection is stable, and the structure is simple to implement.

Preferably, the rear cover and the tail portion of the fixing member are connected to each other with a corresponding fitting member, and the rear cover and the tail portion of the fixing member are fitted and coupled by corresponding fitting members. The connection by the fitting member does not require the use of other connecting members, and is simple to implement.

Preferably, the fixing member is an integrally formed member, and the data line is directly enclosed inside the fixing member and is pierced from the tail portion of the fixing member. One-piece molding is simple to implement and low in cost.

Preferably, the fixing member is internally disposed axially with a receiving cavity for receiving the fixed data line. The data line can be placed in the accommodating cavity so that the data line does not cause large sway in the lateral direction, and the fixing effect is better.

Preferably, the fixing member is a split structure, and the fixing member comprises two or more separate members, and the two or more separate members may be fixed to each other. The component body structure can be set to achieve standardized production, and at the same time, a plurality of standard parts are produced, assembled according to needs, cost saving, and simple implementation.

Preferably, the two or more separate parts are fixed to each other by a connecting piece. The connection is reliable through the connection, the connection is stable, and the structure is simple to implement.

Preferably, the mutually connected portions of the two or more separate members are provided with corresponding fitting members, and the two or more fixed member separate members may be fixedly coupled to each other by the corresponding fitting members. The connection by the fitting member does not require the use of other connecting members, and is simple to implement.

Preferably, the fixing member comprises a head member in the axial direction close to the joint body and a tail member away from the joint body, the tail member being rotatable in the axial direction, the positioning structure being included on the cross section of the tail member of the fixing member An outlet slot is provided in one or more directions, and the data line is received from the tail of the fixing member and received into the outlet slot. In this way, the tail member can be rotated as needed, so that the outgoing direction of the data line is in an appropriate position, and it is convenient to use.

According to the above solution, the present invention provides a positioning structure for locating the outgoing direction of the data line at the tail of the fixing member, and the data line can be positioned from the tail of the fixing member and then positioned by the positioning structure, such that the data line connector is arranged. After the access, the data lines can be positioned and fixed to different outlet directions as needed, so that interference with the equipment and the brackets is avoided according to actual needs, and the space is optimized to the maximum extent.

DRAWINGS

1 is a schematic structural view of a data line connector according to an embodiment of the invention;

2 is a schematic structural view of a data line connector according to an embodiment of the invention;

3 is a schematic structural view of a data line connector according to an embodiment of the invention;

4 is a schematic structural view of a data line connector according to an embodiment of the invention;

FIG. 5 is a schematic structural diagram of a data line connector according to an embodiment of the invention; FIG.

6 is a schematic structural view of a data line connector according to an embodiment of the invention;

Figure 7 is a diagram showing the state of use of a data line connector in accordance with an embodiment of the present invention.

detailed description

In order to facilitate the understanding of the present invention, the present invention will be described in more detail below with reference to the accompanying drawings and specific embodiments. It is to be noted that when an element is described as being "fixed" to another element, it can be directly on the other element, or one or more central elements can be present. When an element is referred to as "connected" to another element, it can be a <RTI ID=0.0> </ RTI> </ RTI> <RTIgt; The terms "vertical," "horizontal," "left," "right," and the like, as used in this specification, are for the purpose of illustration.

Unless otherwise defined, all technical and scientific terms used in the specification are the same meaning The terminology used in the description of the present invention is for the purpose of describing particular embodiments and is not intended to limit the invention. The term "and/or" used in this specification includes any and all combinations of one or more of the associated listed items.

The MIDI interface socket shape of each device on the market is standard. However, the angle at which the MIDI interface socket is placed on different products does not have a mandatory standard. The existing anti-rotation groove of the anti-rotation groove can be oriented differently, including upward. (90 degrees), downward (270 degrees), left (180 degrees), right (0 degrees), and oblique (60 degrees) and other different orientations.

The specific structure and implementation of the data line connector of the embodiment of the present invention will be specifically described below.

One embodiment of the present invention is a data line connector including a connector body, the connector body being connected to a data line, wherein: the connection between the connector body and the data line is provided for fixing a fixing member of the joint portion of the joint body and the data line, and the fixing member is provided with a positioning structure for positioning the outgoing direction of the data line with respect to the tail portion of the joint body, and the data line is disposed from the tail portion of the fixing member and positioned by the positioning structure. The design provides a positioning structure for positioning the data lines to different outlet directions at the tail of the fixing component, and the data lines can be positioned from the tail of the fixing component and then positioned by the positioning structure, such that the data line connector is arranged. After the access, the data lines can be positioned and fixed to different outlet directions as needed, so that interference with the equipment and the brackets is avoided according to actual needs, and the space is optimized to the maximum extent. The connector body can be connected to the interface socket, for example, to the interface socket with the anti-rotation slot; the connector body and the data line can be connected by electric welding or the like to realize data communication. The fixing member can directly fix the joint body and the data line by integral injection molding, or can be placed in the inner receiving cavity by the joint body and the data line, or the joint body and the data line can be caught in the inner receiving cavity thereof, or It is fixed by means of gluing, connectors, and the like.

Preferably, the positioning structure comprises an outlet slot in one or more directions disposed on a cross section of the tail of the fixing member, and the data line is received from the tail of the fixing member and received into the outlet slot. This sets the wire slot so that the positioning of the data line is more reliable and does not arbitrarily shake. For example, the cross-section of the tail of the fixing member can be arranged in the upper and lower directions or in the left and right directions in the radial direction. The upper, lower, left and right directions, or any other direction of the outlet groove can be set according to actual needs, so that different The direction of the groove is not enough to meet different space needs. Regardless of the direction in which the notch groove is in the direction, the data line can be routed in the required outgoing direction, maximizing the optimization and saving space. The data line can be directly inserted into the outlet slot after being passed out from the tail of the fixing member, or can be tightly caught in the outlet slot, and the size of the slot can be set according to the diameter of the data line and the actual needs. The cross-sectional shape of the outlet groove may be a square, a circle, a semicircle, or the like, and any shape through which the data line can pass.

Preferably, the tail edge of the fixing member is provided with an edge protruding in the axial direction, and the positioning structure comprises one or more outlets provided on the side edge of the fixing member, the data line is from the tail of the fixing member Pass out and pass through the outlet provided at the side of the tail of the fixed part. Such The setting structure is simple and convenient to implement. For example, the upper and lower sides of the fixing member can be provided with two upper or lower two outlets, or four upper, lower, left and right directions, or any other direction of the outlet, according to actual needs, so that the rotation groove can be different for different directions. To meet different space needs. Regardless of the direction in which the notch groove is in the direction, the data line can be routed in the required outgoing direction, maximizing the optimization and saving space. The data line can be loosely inserted into the outlet port after being passed out from the tail of the fixing member, or can be tightly stuck in the outlet port, and the size of the outlet can be set according to the diameter of the data line and the actual needs. The outlet can be a complete hole or an incomplete opening. The shape of the outlet can be square, circular, semi-circular, etc., and any shape through which the data line can pass.

Preferably, the fixing member further includes a rear cover for closing the tail of the fixing member, the rear cover is disposed at a tail portion of the fixing member, and the rear cover is detachably coupled to a tail portion of the fixing member. The rear cover is set to make the positioning and fixing of the data lines better. The shape and size of the back cover may be set according to actual needs. For example, the shape and size of the back cover may be set to be consistent with or correspond to the cross-sectional shape of the tail portion of the fixing member, so that the sealing effect is better; if the fixing member is The tail edge is provided with an axially protruding edge, and the back cover can be sized smaller than the tail of the fixing member, and the back cover can be embedded and fixed into the side edge of the tail of the fixing member; the cross section of the tail of the fixing member can be It is a circle, a square, a semicircle, an irregular shape, etc., and the back cover can also be set to a circular shape, a square shape, a semicircular shape, an irregular shape, or the like according to the shape of the cross section of the tail portion of the fixing member.

Preferably, the positioning structure includes one or more outlets disposed at a peripheral edge of the back cover, the data lines passing through the tail of the fixing member and passing through the outlet provided at the back cover. For example, the upper and lower left and right two outlets can be arranged at the peripheral edge of the rear cover, or the upper, lower, left and right directions, or any other direction of the outlet, can be set according to actual needs, so that the rotation grooves can be oriented for different directions. Gap, to meet different space needs. Regardless of the direction in which the notch groove is in the direction, the data line can be routed in the required outgoing direction, maximizing the optimization and saving space. The data line can be loosely inserted into the outlet of the back cover after being passed out from the tail of the fixing member, or can be tightly stuck in the outlet, which can be according to the diameter of the data line and the actual needs. Set the size of the outlet. The outlet can be a complete hole or an incomplete opening. The shape of the outlet can be square, circular, semi-circular, etc., and any shape through which the data line can pass.

Preferably, the positioning structure comprises an outlet groove disposed in one or more directions on a cross section of the tail portion of the fixing member, and an outlet groove disposed in the one or more directions corresponding to the outlet groove of the tail portion of the fixing member on the back cover; When the rear cover is closed, the outlet groove provided at the tail of the fixing member and the outlet groove provided on the rear cover form a receiving cavity, and the data line passes through the tail portion of the fixing member and is fixed by being accommodated in the receiving cavity. This arrangement makes the fixing and positioning of the data line more stable and stable, and can buffer the pulling force to prevent the wire and the welded portion of the plug from falling off due to the large pulling force. For example, the direction of the cross section of the tail of the fixing member may be arranged in the upper and lower directions or in the left and right directions, or the upper, lower, left and right directions, or any other direction of the outlet groove may be provided according to actual needs; likewise, the back cover is The corresponding position of the outlet groove at the tail of the fixing member is provided with the outlet groove in the same direction, so that the gap of the rotation stop groove in different directions can be satisfied to meet different space requirements. Regardless of the direction in which the notch groove is in the direction, the data line can be routed in the required outgoing direction, maximizing the optimization and saving space. The data line can be loosely inserted into the wire slot after being passed out from the tail portion of the fixing member, or can be tightly clamped in the receiving groove formed by the outlet groove of the tail portion of the fixing member and the outlet groove of the back cover, according to the data line. The diameter and the actual size of the wire trough need to be set. The cross-sectional shape of the outlet groove may be a square, a circle, a semicircle, or the like, and any shape through which the data line can pass.

Preferably, the rear cover and the tail of the fixing member are connected by a connecting member. The connection is reliable through the connection, the connection is stable, and the structure is simple to implement. For example, a screw hole may be provided at a corresponding portion of the rear cover and the tail portion of the fixing member, and screwed into the corresponding screw hole to fix both. Of course, in addition to the connector, it can be fixed by other means, such as by adhesive fixing, magnetic fixing, and the like.

Preferably, a portion of the rear cover and the tail portion of the fixing member are connected to each other with a corresponding fitting member. The connection by the fitting member does not require the use of other connecting members, and is simple to implement. For example, a snap member that can be engaged with each other can be provided at a corresponding portion of the rear cover and the tail portion of the fixing member.

Preferably, the fixing member is internally disposed axially with a receiving cavity for receiving the fixed data line. Number The data line can be placed in the accommodating cavity so that the data line does not cause large sway in the lateral direction, and the fixing effect is better. For example, the data line may be loosely placed in the accommodating cavity, and the size of the accommodating cavity is larger than the size of the data line, so that a certain movable space may be generated to prevent the data line from being squeezed; or the data line may be stuck into the accommodating cavity. The size of the accommodating cavity is the same as the size of the data line, so that the fixing effect is better, and the data line does not sway in the lateral direction.

Preferably, the fixing member is an integrally formed member, and the data line is directly enclosed inside the fixing member and is pierced from the tail portion of the fixing member. One-piece molding is simple to implement and low in cost. For example, a rubber or other material may be used to form a fixing member by an injection molding method, and after the joint body is connected to the data line, the joint body, the data line and the fixing member are fixedly integrally formed by injection molding.

Preferably, the fixing member is a split structure, and the fixing member comprises two or more separate members, and the two or more separate members may be fixed to each other. The component body structure can be set to achieve standardized production, and at the same time, a plurality of standard parts are produced, assembled according to needs, cost saving, and simple implementation. For example, the fixing member can be provided as two separate members, and the two separate members have the same shape and size, so that only one separate member needs to be produced, and assembled into a plurality of fixed members according to the required number. Of course, it is also possible to set three, four or more separate parts as needed.

Preferably, the two or more separate parts are fixed to each other by a connecting piece. The connection is reliable through the connection, the connection is stable, and the structure is simple to implement. For example, screw holes may be provided in corresponding portions of the respective split parts, and the screws may be screwed into the corresponding screw holes to fix the two. Of course, in addition to the connector, it can be fixed by other means, such as by adhesive fixing, magnetic fixing, and the like.

Preferably, the mutually connected portions of the two or more separate members are provided with corresponding fitting members, and the two or more fixed member separate members may be fixedly coupled to each other by the corresponding fitting members. The connection by the fitting member does not require the use of other connecting members, and is simple to implement. For example, snap members that can be snapped to each other can be provided at respective portions of the respective split parts.

Preferably, the fixing member includes a head member in the axial direction close to the joint body and a tail member away from the joint body, the tail member being rotatable in the axial direction, the positioning structure including In one or more directions of the outlet grooves provided on the cross section of the fixing member tail member, the data wires are taken out from the tail portion of the fixing member and received in the outlet groove. In this way, the tail member can be rotated as needed, so that the outgoing direction of the data line is in an appropriate position, and it is convenient to use. For example, a cross-section on the tail of the fixing member may be provided with an outlet slot or a plurality of outlet slots in any direction; the data line is received from the tail of the fixing member and received into the outlet slot, and the head member may be set to a fixed state. The tail member is arranged to be rotatable counterclockwise or clockwise, or can be rotated in both directions; the head member can also be set to be rotatable about the axis as needed; it can be set in the middle of the fixed member The rotary axis is rotated, and other rotation methods can be used. Rotate the outlet slot to the corresponding position as needed, so that it can meet the different space requirements for the notch groove in different directions. Regardless of the direction in which the notch groove is in the direction, the data line can be routed in the required outgoing direction, maximizing the optimization and saving space. The data line can be loosely inserted into the wire slot after being passed out from the tail portion of the fixing member, or can be tightly clamped in the receiving groove formed by the outlet groove of the tail portion of the fixing member and the outlet groove of the back cover, according to the data line. The diameter and the actual size of the wire trough need to be set. The cross-sectional shape of the outlet groove may be a square, a circle, a semicircle, or the like, and any shape through which the data line can pass.

Embodiments of the present invention will be described below with reference to the accompanying drawings.

Example 1:

As shown in FIG. 1, a connector of a data line includes a connector body, that is, a data line plug 101, a data line plug 101 is connected to the data line 102, and a connection part 300 is fixed at a connection between the data line plug 101 and the data line 102, and is fixed. The component 300 includes a first split component 301 and a second split component 302. The fixed component 300 is circular in cross section with respect to the tail portion of the data line plug 101, and has two directions of outgoing slots in the transverse direction. In the illustrated direction of the embodiment, the first outgoing slot 201 in the left direction and the second outgoing slot 202 in the right direction are provided. The first split member 301 and the second split member 302 are detachably connected, and the joint portions of the first split member 301 and the second split member 302 are respectively provided with corresponding fitting members, as shown in the figure. A split member 301 is provided with a recess 3011 at the joint portion, and the second split member 302 is provided with a protrusion 3021 at the joint portion. The first split member 301 and the second split member 302 are axially disposed with a receiving cavity (not shown) for accommodating the fixed data line, and the first split member 301 and the second split member 302 are fitted to each other. When the data line 102 is wrapped and positioned in the accommodating cavity, the protrusion 3021 of the second split part 302 is embedded in the recess 3011 of the first split part 301 to achieve a fitting connection, the first split part 301 and When the second split members 302 are fitted to each other, the data line plug 101 and the data line 102 can be fixedly clamped together. In use, the data line 102 is escaping from the tail portion of the fixing member 300 (relative to the connector body, that is, the tail of the data line plug 101) to the first outlet slot 201 (the outlet slot of the specific outlet can be selected according to actual needs) The positioning of the data line 102 is implemented. The size of the first outlet slot 201 is substantially equal to the diameter of the data line 102, so that the data cable 102 can be firmly locked in the first outlet slot 201 for fixing.

Example 2:

As shown in FIG. 2, a connector of a data line includes a data line 102, a connector body, that is, a data line plug 101, a back cover 400 disposed at a tail portion of the fixing member, a data line plug 101 connected to the data line 102, and a data line plug. A fixing member 300 is provided at a joint of the data line 102 and the data line 102. The fixing member 300 is a member integrally molded by injection molding. The fixing member 300 and the data line plug 101 and the data line 102 are fixed by injection molding, and the fixing member 300 is axially disposed inside. There is a receiving cavity (not shown) for accommodating the fixed data line. The fixing member 300 is circular in cross section with respect to the tail portion of the data line plug 101, and a transverse groove is provided in two directions in the radial direction. The illustrated first embodiment of the present embodiment is a first outlet slot 201 in the left direction and a second outlet slot 202 in the right direction. The rear cover 400 is shaped and sized to correspond to the cross-sectional shape of the tail portion of the fixing member, and the shape of the rear cover 400 is a shape that can be fitted into the tail portion of the fixing member 300. A first screw hole 401 is disposed on the rear cover 400, and a second screw hole 303 is disposed on the tail portion of the fixing member 300. The first screw hole 401 corresponds to the position of the second screw hole 303. In use, the data line 102 is positioned from the tail of the fixing member 300 to be accommodated in the second outlet slot 202 (the outlet slot that can select a specific outlet according to actual needs) to realize the positioning of the data line 102. The size of the second outlet slot 202 is slightly larger than the diameter of the data line 102. The back cover 400 is then closed to the tail of the fixing member 300, first The screw hole 401 and the second screw hole 303 are coincident, and are screwed into the first screw hole 401 and the second screw hole 303 by screws 500 to fix and position the data line 102.

Example 3:

As shown in FIG. 3, the difference between Embodiment 3 and Embodiment 2 is that in the embodiment 3, the tail edge of the fixing member 300 is provided with an axially protruding side edge 303, and the tail member 303 of the fixing member 300 is provided with two outlet ports. There is no wire groove provided in the cross section of the fixing member 300. In the illustrated direction of the embodiment, the first outlet port 203 in the left direction and the second outlet port 204 in the right direction are provided. In use, the data line 102 passes through the tail portion of the fixing member 300 and passes through the first outlet port 203 disposed at the trailing edge 303 of the fixing member 300 (the outlet of the specific outlet can be selected according to actual needs) to realize the data line 102. Positioning. The size of the first outlet 203 is slightly larger than the diameter of the data line 102. Then, the rear cover 400 is closed to the tail portion of the component 300, and the first screw hole 401 and the second screw hole 303 are coincident, and can be screwed into the first screw hole 401 and the second screw hole 303 by the screw 500. The data line 102 is fixed and positioned.

Example 4:

As shown in FIG. 4 and FIG. 5, a connector of a data line includes a data line 102, a connector body, that is, a data line plug 101, a back cover 400 disposed at a tail portion of the fixing member, and a data line plug 101 connected to the data line 102. A fixing member 300 is provided at a connection between the data line plug 101 and the data line 102, and the fixing member 300 is a member integrally molded by injection molding, and the fixing member 300 and the data line plug 101 and the data line 102 are fixed by injection molding, and the inside of the fixing member 300 is fixed. The accommodating cavity (not shown) accommodating the fixed data line is axially disposed, and the fixing member 300 is circular in cross section with respect to the tail portion of the data line plug 101, and is disposed in four directions in the radial direction in the transverse direction. The outlet slot, in the illustrated direction of the embodiment, is a first outlet slot 201 in the left direction and a second outlet slot 202 in the right direction, an upward third outlet slot 205 and a downward fourth outlet slot 206. The rear cover 400 is shaped and sized to correspond to the cross-sectional shape of the tail portion of the fixing member, and the shape of the rear cover 400 is a shape that can be fitted into the tail portion of the fixing member 300. A first screw hole 401 is disposed on the rear cover 400, and a second screw hole 303 is disposed on the tail portion of the fixing component 300, and the first screw hole 401 is The positions of the second screw holes 303 correspond to each other. In use, the data line 102 is positioned from the tail of the fixing member 300 and accommodated in the first outlet slot 201 (the outlet slot in which the specific outlet can be selected according to actual needs). The size of the first outlet slot 201 is slightly larger than the diameter of the data line 102. Then, the rear cover 400 is closed to the tail portion of the component 300, and the first screw hole 401 and the second screw hole 303 are coincident, and can be screwed into the first screw hole 401 and the second screw hole 303 by the screw 500. The data line 102 is fixed and positioned.

Example 5:

As shown in FIG. 6, a connector of a data line includes a connector body, that is, a data line plug 101, a data line plug 101 is connected to the data line 102, and a connection part 300 is fixed at a connection between the data line plug 101 and the data line 102, and is fixed. The member 300 includes a head member (fourth split member 304) and a tail member (third split member 303) in the axial direction, and the cross section of the fixed member 300 with respect to the tail portion of the data line plug 101 is circular, and its cross section An outlet groove having one direction is disposed in the radial direction in the direction, and is a left first outlet groove 201 in the illustrated direction of the embodiment. The fourth split member 304 is fixed and non-rotatable with the data line plug 101. The third split member 303 can be rotated counterclockwise or clockwise along the rotating shaft disposed on the intermediate member. The fixed member 300 is axially disposed to accommodate the fixed data line. The receiving chamber (not shown) is positioned to wrap the data line 102 in the receiving chamber. In use, the data line 102 is received from the tail of the third split member 303 (relative to the connector body, that is, the tail of the data line plug 101) into the first outlet slot 201 to achieve positioning of the data line 102. The size of the first outlet slot 201 is substantially equal to the diameter of the data line 102, so that the data cable 102 can be firmly locked in the first outlet slot 201 for fixing. When it is required to change the outgoing direction of the data line, it is only necessary to rotate the third split member 303 to a suitable position so that the outgoing direction of the data line satisfies the requirement.

7 is a view showing a state of use of a data line connector according to an embodiment of the present invention. On a typical effect board, it can be seen that the bracket 603, the first device 601 and the second device 602 are used as a connector body, that is, a data line plug. After the 101 is inserted into the MIDI interface socket, the data line can be routed from the outlet or the outlet slot at the end of the fixed component 300, so that the user can easily adjust the outgoing line by himself. The angle avoids interference with the front and rear equipment and the bracket, saving space.

The data line connector according to the embodiment of the invention can be used for a MIDI data line connector, and can also be applied to other types of data line connectors; it can be specifically applied to a data line connector with a rotation stop groove, and can also be applied to other data lines. Data line connector with stop groove. The data line connector according to the embodiment of the present invention can be applied to a connector of a data line for transmitting data, and can also be used for transmitting an electrical connector of an electric plug and a wire.

It is to be noted that the preferred embodiments of the present invention are described in the specification of the present invention, and the present invention may be embodied in many different forms and not limited to the embodiments described herein. These examples are not intended to be limiting as to the scope of the present invention, which is intended to provide a more thorough understanding of the present disclosure. Further, the above various technical features are further combined with each other to form various embodiments not enumerated above, and are considered as the scope of the description of the present invention; further, those skilled in the art can improve or change according to the above description. All such improvements and modifications are intended to be included within the scope of the appended claims.

Claims (16)

1. A data line connector includes a connector body, wherein the connector body is connected to a data line, wherein: a connection portion of the connector body and the data line is provided with a fixing component for fixing a connection portion between the connector body and the data line, and the fixing component is opposite to the connector The tail portion of the body is provided with a positioning structure for positioning the outgoing direction of the data line, and the data line is passed through the positioning portion from the tail portion of the fixing member.
2. A data line connector according to claim 1, wherein said positioning structure comprises an outlet groove in one or more directions provided on a cross section of the tail portion of the fixing member, the data line being passed out from the tail portion of the fixing member to the outlet line In the slot.
3. The data line connector according to claim 1, wherein a tail edge of said fixing member is provided with an edge projecting in the axial direction, and said positioning structure includes one or more outlet ports provided on a side edge of the fixing member The data line passes through the tail of the fixing member and passes through the outlet opening provided at the side edge of the fixing member.
4. A data cable connector according to claim 1, wherein said fixing member further comprises a rear cover for closing the tail of the fixing member, said rear cover being provided at a tail portion of said fixing member, said rear cover and a tail portion of said fixing member being Disassemble the connection.
5. The data line connector according to claim 4, wherein said positioning structure comprises an outlet groove in one or more directions disposed on a cross section of the tail portion of the fixing member, the data line being passed out from the tail portion of the fixing member to the outlet line In the slot.
6. The data line connector according to claim 4, wherein a tail edge of said fixing member is provided with an axially projecting side, and said positioning structure includes one or more outlets provided on a side edge of the fixing member. The data line passes through the tail of the fixing member and passes through an outlet provided at the side edge of the fixing member.
7. A data cable connector according to claim 4, wherein said positioning structure comprises one or more outlet openings provided at a peripheral edge position of the rear cover, the data wires passing through the tail portion of the fixing member and passing through the rear cover Outlet.
8. The data line connector according to claim 4, wherein said positioning structure comprises an outlet groove disposed in one or more directions on a cross section of the tail portion of the fixing member, and a correspondingly disposed on the rear cover corresponding to the outlet groove of the tail portion of the fixing member An outlet slot in one or more directions; when the rear cover is closed, the outlet slot provided at the tail of the fixing member and the outlet slot provided on the rear cover form a receiving cavity, and the data line is passed out from the tail of the fixing member to receive Positioning is fixed in the accommodating chamber.
9. The data line connector according to claim 4, wherein the rear cover and the tail of the fixing member are connected by a connecting member.
10. The data line connector according to claim 4, wherein a portion where the rear cover and the tail portion of the fixing member are connected to each other is provided with a corresponding fitting member, and the tail portions of the rear cover and the fixing member are embedded by the corresponding fitting members Connected.
11. The data cable connector according to claim 1, wherein said fixing member is an integrally molded member, and said data line is directly enclosed inside said fixing member and is passed out from a tail portion of said fixing member.
12. The data line connector according to claim 1, wherein said fixing member is internally provided with a receiving cavity for accommodating the fixed data line.
13. The data line connector of claim 1 wherein said securing member is a split structure and said securing member comprises one or more separate members, one or more of the separate members being connectable to each other.
14. The data line connector according to claim 13, wherein said two or more separate members are fixed to each other by a connecting member.
15. The data line connector according to claim 13, wherein the interconnection portions of the two or more separate members are provided with corresponding fitting members, and the two or more fixed member separate members can be inserted by corresponding The components are fixedly coupled to each other.
16. The data line connector according to claim 13, wherein said fixing member includes a head member in the axial direction close to the joint body and a tail member away from the joint body, said tail member being rotatable in the axial direction, said positioning The structure includes an outlet slot in one or more directions disposed on a transverse section of the tail member of the stationary member, the data line being received from the tail of the stationary member and received into the outlet slot.

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