Patent Description:
In recent years, with the continuous development of power electronics, in order to meet the market demand and create technological breakthroughs, there are very strict restrictions on designing the high-voltage harness direction of the automobile inverter in the layout of the whole vehicle. In the conventional inverters, the high-voltage harness direction is single, which cannot meet the multi-directional wiring requirements and cannot realize the high-voltage protection function.

Therefore, it is necessary to provide a junction box which can not only meet the multi-directional wiring requirements, but also realize the high-voltage protection function.

Document <CIT>, according to its abstract, discloses an electrical equipment, comprising a casing and an electronic control unit, said electronic control unit comprises at least one safety switch configured for switching off the electronic control unit when said at least one safety switch is released and for switching on the electronic control unit when said at least one safety switch is pressed. The electrical equipment further comprises a pin comprising an elongated body having a proximal end and a distal end, said elongated body being configured so that in a position, called closed position, said distal end abuts against an element of the casing and said proximal end abuts against the at least one safety switch for switching the electronic control unit on.

Document <CIT>, according to its abstract, discloses a power converting connector which is composed of a plug component and a socket component. The plug component includes a plug casing, a plug back cover, a male terminal component, and a pin component. The socket component includes a socket casing, socket back cover and a panel, which are integrated into a single body. A floating component capable of moving in three directions relative to the socket casing is arranged in an accommodating space spliced by the socket casing and the panel. The floating component includes a female terminal component and a jack component. An adapter is arranged on the socket back cover. The male terminal component is connected with the female terminal component, and the pin component is connected with the jack component. The plug component and the socket component are electrically connected. According to the invention, the connector has a delicate structure and adopts the floating component which can float in three directions on the X-axis, Y-axis, and Z-axis; and the jack component and the female terminal component in the socket component can be floated as following the shaking of a car to ensure that the male terminal, the female terminal, the pin, and the jack are always effectively connected.

Document <CIT>, according to its abstract, discloses a connector. The connector includes: the terminal receiving portion provided with the terminal fittings to be connected to the electrodes of the connector attachment portion; the cover member for covering the terminal receiving portion; the first interlock connector projecting from the cover member; and the second interlock connector provided on the terminal receiving portion and configured to be fitted to the first interlock connector. When the cover member covers the terminal receiving portion, the first interlock connector and the second interlock connector are fitted to each other, thereby the connector detects that the cover member covers the terminal receiving portion and allows the terminal fittings to be energized with the electrodes of the connector attachment portion. The terminal receiving portion is provided with: the bolting chambers in which the terminal fittings and the electrodes are fastened with bolts; the insertion hole into which the first interlock connector is inserted; and the partition wall separating the bolting chambers from the insertion hole. Further, the second interlock connector is provided at a position corresponding to the insertion hole.

Document <CIT>, according to its abstract, discloses an electrical junction box for use in electrical equipment for automotive vehicles, etc., has a junction box body and at least two box connectors for connecting wire harnesses to inner circuits of the junction box. Each of the at least two box connectors comprises at least one cable connector for directly connecting the remaining wire harness which are not connected to the junction box to each other. Both the box connectors and cable connectors are accommodated in the junction body box. The cable connectors are constructed, so as to be connected to each other when the box connectors are engaged with the junction box body.

Document <CIT>, according to its abstract, discloses a wiring box of a drive motor controller of a pure electric vehicle, comprising a box body, a cover plate and wiring units, wherein the wiring units are arranged in the box body; the wiring units inside the box body include a DC positive (+) and negative (-) pole wiring unit and an AC U-phase, V-phase and W-phase wire wiring unit; a power wire of a DC power supply and a power wire of an AC power supply are positioned in the same wiring box; an installation combining surface of the box body and the cover plate is an inclined plane; the bottom of the box body is provided with a wiring hole which corresponds to each wiring unit; a power wire positioned in the center of a high-voltage shielding wire upwards penetrates through the bottom wiring hole and is installed and fixed by bolts positioned on the corresponding wiring unit, and a wiring direction is perpendicular to the bottom installation surface of the motor controller; and a shielding layer positioned on the outer layer of the high-voltage shielding wire is installed and fixed at the bottom of the wiring box through a wiring terminal by respectively using two screws.

In view of the above problems, the present disclosure proposes an inverter junction box to solve or partially solve the above problems.

In order to achieve the above object, the technical solutions of the present disclosure are as follows:
The present disclosure provides an inverter junction box. The inverter junction box comprises a casing, a cover plate and a knockout pin, a high-voltage busbar terminal, wherein.

Further, the conductive column is made of copper.

Further, a through hole is provided in a central part of the conductive column, and the high-voltage busbar terminal can be connected to the incoming terminal of the inverter via the through hole and a bolt.

Further, the casing is further provided therein with a positioning plate for fixing the insulating body and the knockout pin at a middle position of the casing.

Further, the casing has a cylindrical shape or a regular quadrangular prism shape as a whole, the insulation body extends along a diameter of the cylindrical shape or a diagonal of the regular quadrangular prism shape with two ends abutting against the casing, and the two conductive columns are symmetrically provided on the diameter or the diagonal.

Further, outer end sides of the high-voltage busbar terminal are provided with a number of insulating medium support protrusions.

Further, the connecting part and the casing are arranged to be perpendicular to each other, the connecting part is provided therein with a positive connecting hole and a negative connecting hole, and the positive connecting hole and the negative connecting hole are communicated with an interior of the casing.

Further, the casing is provided thereon with a number of longitudinally penetrating installation holes, and the cover plate is also provided with installation holes at corresponding positions.

Further, the casing is provided thereon with a positioning hole engaging with a positioning column on the inverter, or the casing is provided with a positioning column engaging with a positioning hole on the inverter.

The above inverter junction box has the following advantages.

In the inverter junction box according to the present disclosure, the knockout pin cooperates with the protection device on the inverter, which can realize the high-voltage protection when opening the cover plate of the junction box to perform wire connection, and effectively ensure the safety of operator and equipment. The wire connecting direction of the junction box can be changed by providing the connecting part with a different orientation or by rotating the casing during installation to change the orientation of connecting part.

By reading the detailed description of the preferred embodiments below, various other advantages and benefits will become clear to a person of ordinary skill in the art. The accompanying drawings are only used for the purpose of illustrating the preferred embodiments. Moreover, throughout the drawings, the same reference numerals are used to denote the same components. In the drawings:.

In the drawings: <NUM>. casing, <NUM>. cover plate, <NUM>. high voltage busbar terminal, <NUM>. knockout pin, <NUM>. positioning hole, <NUM>. installation hole, <NUM>. conductive column.

Illustrative embodiments of the present disclosure will be described in more detail with reference to the drawings. Although the drawings show the illustrative embodiments of the present disclosure, it should be understood that the present disclosure can be implemented in various ways. On the contrary, the embodiments are provided for a more thorough and complete understanding of the present disclosure, so as to fully convey the scope of the present disclosure to those skilled in the art.

An embodiment of the present disclosure provides an inverter junction box. Of course, the junction box in the present disclosure may also be used in other similar scenarios.

As shown in <FIG>, the inverter junction box comprises casing <NUM>, cover plate <NUM> and knockout pin <NUM>. The cover plate <NUM> is detachably connected with the top part of casing <NUM>. One end of the knockout pin <NUM> is detachably connected to the bottom part of the cover plate <NUM>, and the other end abuts against a protection device on the inverter. The knockout pin <NUM> may be connected and fixed with the cover plate <NUM> by screws. When the knockout pin <NUM> abuts against the protective device, the high-voltage protection will not be triggered. When the cover plate <NUM> of the junction box is opened, since the knockout pin <NUM> is fixedly connected with the cover plate <NUM>, the knockout pin <NUM> is separated from the protective device, and at this moment the high-voltage protection will be triggered, which can effectively ensure the safety of operator and equipment.

One side of the casing <NUM> is equipped with a connecting part, and the external cables can be connected with the interior of the junction box via the connecting part. The bottom part of the casing <NUM> is a hollow structure, and abuts against the incoming terminal of the inverter. The design of the hollow structure facilitates the connection between the internal structure of the junction box and the inverter.

In an embodiment, as shown in <FIG>, the inverter junction box further comprises a high voltage busbar terminal <NUM>.

The high voltage busbar terminal <NUM> comprises an insulating body and two conductive columns <NUM>, and the conductive columns <NUM> are respectively inserted in the insulating body. One end of the conductive column <NUM> is connected with the external cable, and the other end is connected with the incoming terminal of the inverter. Its function is to realize the connection between the external cable and the inverter device. The design of the insulation body can realize the relative fixation of the two conductive columns <NUM>. The insulation body part between the two conductive columns <NUM> may be a hollow structure, which facilitates heat dissipation and material saving.

In this embodiment, the design of the high-voltage busbar terminal <NUM> can realize the connection between the inverter device and external cables of different directions, so that the high-voltage harness of external cables is not restricted by the whole vehicle structure, and meet the requirements of multi-directional wiring of the inverter. The connection structure between the inverter device and the junction box shown in <FIG> does not use the high-voltage busbar terminal <NUM>, and the external cable is directly connected with the inverter terminal after entering the connection box. The connection structure shown in <FIG> uses the high-voltage busbar terminal <NUM>, the change of the wire connecting direction of the inverter device is realized, and the junction box can also realize other wire connecting directions of the inverter device.

In an embodiment, the conductive column <NUM> is made of copper. Of course, the conductive column <NUM> may also be made of other metal materials with excellent conductivity.

In an embodiment, a central part of the conductive column <NUM> on the high-voltage busbar terminal <NUM> is provided with a through hole. As can be seen from <FIG>, the conductive column <NUM> is fixed on the incoming terminal of the inverter via the through hole and a bolt, so as to realize the electrical conductivity between the conductive column <NUM> and the incoming terminal, and the external cable is also fixedly connected with the conductive column <NUM> via the bolt.

In an embodiment, as shown in <FIG>, a positioning plate is further provided in the casing <NUM>. Holes are opened on the positioning plate at positions corresponding to the insulating body and knockout pin <NUM>, and the insulating body and knockout pin <NUM> can pass through the holes. The positioning plate is used to fix the insulating body and knockout pin <NUM> at a middle position of the casing <NUM> to prevent the insulating body and knockout pin <NUM> from shaking in the casing <NUM>.

In an embodiment, the casing <NUM> has a cylindrical shape or a regular quadrangular prism shape as a whole. The casing <NUM> may be designed into other shapes as required, such as a rectangle. The insulating body extends along the diameter of the cylinder or the diagonal of the regular quadrangular prism, and abuts against the casing. The two conductive columns <NUM> are symmetrically disposed on the diameter or the diagonal. This structure makes the insulating body more firmly fixed in the casing, and also effectively reduces the volume of the casing <NUM> and makes the junction box smaller as a whole.

In an embodiment, as shown in <FIG>, the outer end sides of the high-voltage busbar terminal <NUM> are provided with a number of insulating medium support protrusions, which respectively abut against the inner wall of the casing <NUM> to limit the position of the high-voltage busbar terminal <NUM> and fix it.

In an embodiment, it can be seen from <FIG> that the connecting part is perpendicular to the casing <NUM>. For example, they can be arranged in an L-shape. A notch is provided at a corner of the casing <NUM> below the connecting part. The design of the notch can save material and reduce weight. A positive connecting hole and a negative connecting hole are provided in the connecting part, and the positive connecting hole and the negative connecting hole are communicated with the interior of the casing. The positive and negative poles of the external cable may pass through the positive and negative connecting holes respectively to connect with the conductive columns <NUM> or the incoming terminals of the inverter.

In an embodiment, as shown in <FIG> and <FIG>, the casing <NUM> is provided with a number of longitudinally penetrating installation holes <NUM>, the cover plate <NUM> is also provided with installation holes <NUM> at corresponding positions, and the position of the installation holes <NUM> on the casing <NUM> are consistent with the position of the installation holes <NUM> on the cover plate <NUM>. Screws or bolts pass through the installation holes <NUM> to realize the fixation between the cover plate <NUM> and the casing <NUM>, as well as the fixation between the casing <NUM> and the inverter device.

In an embodiment, as shown in <FIG> and <FIG>, the casing <NUM> is provided with a positioning hole <NUM> that engages with a positioning column on the inverter. The positioning hole <NUM> may completely penetrate the casing <NUM>. Through the engagement of the positioning hole and the positioning column, the position of the casing <NUM> can be fixed. Of course, the positions of the positioning hole and the positioning column may also be interchanged.

Claim 1:
An inverter junction box, comprising: a casing (<NUM>), a cover plate (<NUM>) and a knockout pin (<NUM>), a high-voltage busbar terminal, wherein
the cover plate (<NUM>) is detachably connected with a top part of the casing (<NUM>);
one end of the knockout pin (<NUM>) is detachably connected with a bottom part of the cover plate (<NUM>), and the other end of the knockout pin (<NUM>) can abut against a protection device on the inverter;
one side of the casing (<NUM>) is provided with a connecting part that is connected with an external cable; and
a bottom part of the casing (<NUM>) is a hollow structure and abuts against an incoming terminal of the inverter,
the high-voltage busbar terminal comprises an insulating body and two conductive columns (<NUM>), and the conductive columns (<NUM>) are respectively inserted in the insulating body,
characterized in that:
in a first orientation of the inverter junction box, the incoming terminal of the inverter are connected to the external cable via the two conductive columns (<NUM>) of the high-voltage busbar terminal,
in a second orientation of the inverter junction box, the external cable is directly connected with the incoming terminal of the inverter after entering the inverter junction box and does not use the high-voltage busbar terminal,
when the knockout pin (<NUM>) abuts against the protection device, the high-voltage protection will not be triggered, when the cover plate (<NUM>) of the junction box is opened, so that the knockout pin (<NUM>) is fixedly connected with the cover plate (<NUM>) and separated from the protection device, the high-voltage protection will be triggered.