CN219627431U - Power distribution equipment - Google Patents

Abstract

The utility model provides power distribution equipment which comprises a mains supply input end, a power distribution input end, an energy storage input end, an electric connecting piece and a sensor. The electric connecting piece comprises a first electric connecting part and a second electric connecting part, the first electric connecting part is connected with the mains supply input end, the second electric connecting part is respectively connected with the power distribution input end and the energy storage input end, and the power distribution input end and the energy storage input end are electrically connected with the mains supply input end through the electric connecting piece. The sensor is sleeved on the first electric connection part and is electrically connected with a control board of the power distribution equipment. The sensor is arranged on the first electric connection part, so that current data output from the mains supply input end to the power distribution input end and the energy storage input end through the first electric connection part can be obtained. The power distribution equipment does not need an external ammeter, can monitor the power supply condition of the mains supply input end input to each branch, and meets the requirement of a user for conveniently monitoring the electric quantity.

Description

Power distribution equipment

Technical Field

The utility model relates to the technical field of power distribution, in particular to power distribution equipment.

Background

The sensor can be installed in the distribution equipment to monitor input voltage, current, power, frequency and the like, and the power supply condition is monitored in real time, but along with the development of energy storage technology, the related distribution equipment can be connected into an energy storage power supply for distribution besides the external mains supply for distribution, but the related distribution equipment can only monitor the power supply condition of the mains supply input to each branch, cannot meet the requirement of a user for conveniently monitoring electric quantity, and is inconvenient for the user to use.

Disclosure of Invention

In order to solve the problems in the prior art, the utility model provides the power distribution equipment which has the power monitoring function and is convenient to use.

The embodiment of the utility model provides power distribution equipment which comprises a mains supply input end, a power distribution input end, an energy storage input end, an electric connecting piece and a sensor. The electric connecting piece comprises a first electric connecting part and a second electric connecting part, wherein the first electric connecting part is connected with the second electric connecting part, the first electric connecting part is connected with the mains supply input end, the second electric connecting part is respectively connected with the power distribution input end and the energy storage input end, and the power distribution input end and the energy storage input end are electrically connected with the mains supply input end through the electric connecting piece. The sensor is sleeved on the first electric connection part and is electrically connected with the control panel of the power distribution equipment.

In one possible embodiment, the second electrical connection comprises a first branch section and a second branch section connected, the first branch section being connected to the power distribution input, the second branch section being connected to the energy storage input.

In one possible embodiment, the first branch segment and the second branch segment are electrically connected to the first electrical connection, and the first branch segment and the second branch segment extend to two opposite sides of the first electrical connection.

In one possible embodiment, the direction of extension of the first branch flow section intersects the direction of extension of the second branch flow section.

In one possible embodiment, the extending direction of the first electrical connection portion is a first direction, the extending direction of the second electrical connection portion is a second direction, and the first direction intersects the second direction.

In one possible implementation manner, the sensor includes a sensing portion, a threading hole is formed in the sensing portion, the first electrical connection portion passes through the threading hole, and the sensing portion is used for being electrically coupled with the first electrical connection portion.

In one possible embodiment, the power distribution apparatus further includes a main body portion, and the sensor further includes a fixing portion connected with the sensing portion, the fixing portion including a positioning column disposed toward the main body portion.

In one possible embodiment, the main body portion is provided with two spaced limiting protrusions, and the fixing portion is disposed between the two limiting protrusions.

In one possible embodiment, the electrical connector is provided with a positioning hole therethrough.

In one possible implementation manner, the utility power input end includes a first main input end and a second main input end which are arranged at an insulation interval, the power distribution input end includes a first input branch set and a second input branch set which are arranged at an insulation interval, one electric connecting piece is electrically connected with the first main input end and the first input branch set, the other electric connecting piece is electrically connected with the second main input end and the second input branch set, and each electric connecting piece is electrically coupled with one sensor respectively.

According to the power distribution equipment, the power distribution input end and the energy storage input end are electrically connected with the mains supply input end through the electric connecting piece, and current input by the mains supply input end can be conducted to the second electric connecting part through the first electric connecting part and then conducted to the power distribution input end and the energy storage input end through the second electric connecting part. The sensor is arranged on the first electric connection part, so that current data output to the power distribution input end and the energy storage input end by the mains supply input end through the first electric connection part can be obtained. The power distribution equipment does not need an external ammeter, can monitor the power supply condition of the mains supply input end input to each branch, and meets the requirement of a user for conveniently monitoring the electric quantity.

Drawings

Fig. 1 is a schematic perspective view of a power distribution device according to an embodiment of the present utility model.

Fig. 2 is an exploded perspective view of a power distribution device according to an embodiment of the present utility model.

Fig. 3 is a schematic partial perspective view of a hidden circuit breaker and a mounting panel of a power distribution device according to an embodiment of the present utility model.

Fig. 4 is a schematic plan view of a hidden circuit breaker and a mounting panel of a power distribution device according to an embodiment of the present utility model.

Fig. 5 is a schematic perspective view of a sensor of a power distribution device according to an embodiment of the present utility model along a top view.

Fig. 6 is a schematic perspective view of a sensor of a power distribution device according to an embodiment of the present utility model along a bottom angle.

Fig. 7 is a schematic perspective view of an implementation manner of an electrical connector of a power distribution device according to an embodiment of the present utility model.

Fig. 8 is a schematic perspective view of another implementation of an electrical connector of a power distribution device according to an embodiment of the present utility model.

Description of the main reference signs

10-Power distribution device 101-mains input 102-Power distribution input

103-energy storage input end 104-main body 105-electric connector

106 sensor 107 breaker 1011 first main input

1012-second main input 1021-first input branch group 1022-second input branch group

1031-first energy storage sub-input 1032-second energy storage sub-input 1041-spacing protrusion

1042-mounting panel 1043-conductive posts 1051-first electrical connections

1052-second electrical connection 1053-locating hole 1054-boss

1061-sensing portion 1062-securing portion 10521-first branch portion

10522-second branch 10611-threading hole 10612-positioning column

10621-positioning slot

The utility model will be further described in the following detailed description in conjunction with the above-described figures.

Detailed Description

The following description will make reference to the accompanying drawings to more fully describe the utility model. Exemplary embodiments of the present utility model are illustrated in the accompanying drawings. This utility model may, however, be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. These exemplary embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the utility model to those skilled in the art. Like reference numerals designate identical or similar components. The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the utility model. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. Furthermore, as used herein, "comprises" and/or "comprising" and/or "having," integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, regions, integers, steps, operations, elements, and/or groups thereof. Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. Furthermore, unless the context clearly defines otherwise, terms such as those defined in a general dictionary should be construed to have meanings consistent with their meanings in the relevant art and the present disclosure, and should not be construed as idealized or overly formal meanings. The following description of exemplary embodiments will be provided with reference to the accompanying drawings. It is noted that the components depicted in the referenced figures are not necessarily shown to scale; and the same or similar components will be given the same or similar reference numerals or similar technical terms.

As will be appreciated by those skilled in the art, a "power distribution device" is a generic term for devices such as high voltage power distribution cabinets, generators, transformers, power lines, circuit breakers, low voltage switchgear, distribution boards, switchboxes, control boxes, and the like in power systems.

As will be understood by those skilled in the art, a "circuit breaker" refers to a switching device that is capable of closing, carrying and breaking current under normal circuit conditions and is capable of closing, carrying and breaking current under abnormal circuit conditions for a specified period of time. "circuit breaker" is also known as an air switch.

As will be understood by those skilled in the art, a "utility input" refers to the conductive end of the electrical device that is connected to a utility line, which refers to an ac grid that is laid down in a municipal power supply system.

As will be understood by those skilled in the art, a "distribution input" refers to a conductive end of an electrical device that is electrically connected to each distribution branch, which is each branch of a circuit through which the same current can pass, and in which the branch is a single circuit element or a series of circuit elements, forming a branch through which the same current flows, each branch of the circuit being referred to as a branch.

As will be understood by those skilled in the art, an "energy storage input" refers to a conductive end of an electrical device that is connected to an energy storage and power supply line, which is a power network that is powered by an energy storage device (e.g., a large mobile power source).

It will be understood by those skilled in the art that a "sensor" refers to a detection device that senses measured information and converts the sensed information into an electrical signal or other information output in a desired form according to a certain rule so as to meet the requirements of information transmission, processing, storage, display, recording, control, and the like.

As will be appreciated by those skilled in the art, a "control board" is a circuit board that contains logic circuitry and that can receive and emit electrical signals.

As will be appreciated by those skilled in the art, a "conductive stud" is a columnar component made of a conductive material, such as a copper stud, having a conductive circuit or transmitting an electrical signal.

As will be understood by those skilled in the art, the "electrical connector", "first electrical connection", "second electrical connection", "first branch section" and "second branch section" are conductive materials having conductive connection capability, and components connected to the "electrical connector", "first electrical connection", "second electrical connection", "first branch section" and "second branch section" may be electrically connected to each other, such as copper sheets.

The sensor can be installed in the distribution equipment to monitor input voltage, current, power, frequency and the like, and the power supply condition is monitored in real time, but along with the development of energy storage technology, the related distribution equipment can be connected into an energy storage power supply for distribution besides the external mains supply for distribution, but the related distribution equipment can only monitor the power supply condition of the mains supply input to each branch, cannot meet the requirement of a user for conveniently monitoring electric quantity, and is inconvenient for the user to use.

In order to solve the problems in the prior art, the utility model provides the power distribution equipment which has the power monitoring function and is convenient to use. The power distribution equipment comprises a mains supply input end, a power distribution input end, an energy storage input end, an electric connecting piece and a sensor. The electric connecting piece comprises a first electric connecting part and a second electric connecting part, wherein the first electric connecting part is connected with the second electric connecting part, the first electric connecting part is connected with the mains supply input end, the second electric connecting part is respectively connected with the power distribution input end and the energy storage input end, and the power distribution input end and the energy storage input end are electrically connected with the mains supply input end through the electric connecting piece. The sensor is sleeved on the first electric connection part and is electrically connected with the control panel of the power distribution equipment. The power distribution input end and the energy storage input end are electrically connected with the mains supply input end through the electric connecting piece, and current input by the mains supply input end can be conducted to the second electric connecting portion through the first electric connecting portion, and then is conducted to the power distribution input end and the energy storage input end through the second electric connecting portion. The sensor is arranged on the first electric connection part, so that current data output to the power distribution input end and the energy storage input end by the mains supply input end through the first electric connection part can be obtained. The power distribution equipment does not need an external ammeter, can monitor the power supply condition of the mains supply input end input to each branch, and meets the requirement of a user for conveniently monitoring the electric quantity.

The following describes in further detail the embodiments of the present utility model with reference to the accompanying drawings.

As shown in fig. 1 to 8, an embodiment of the present utility model provides a power distribution apparatus 10 including a utility power input 101, a power distribution input 102, an energy storage input 103, a main body 104, an electrical connection 105, a sensor 106, and a circuit breaker 107. The utility power input end 101, the distribution input end 102 and the energy storage input end 103 are distributed on the main body 104 at intervals, each end of the electric connector 105 is respectively connected with the utility power input end 101, the distribution input end 102 and the energy storage input end 103, the sensor 106 is matched with the electric connector 105 to acquire electricity consumption data transmitted to the distribution input end 102 and the energy storage input end 103 by the utility power input end 101, the circuit breaker 107 is at least electrically connected with the utility power input end 101 and used for controlling on-off of a main circuit and/or a branch circuit of the power distribution equipment 10, and the circuit breaker 107 is mounted on the mounting panel 1042 of the main body 104.

The electrical connector 105 includes a first electrical connection 1051 and a second electrical connection 1052, the first electrical connection 1051 is connected with the mains input terminal 101, the second electrical connection 1052 is respectively connected with the power distribution input terminal 102 and the energy storage input terminal 103, and the power distribution input terminal 102 and the energy storage input terminal 103 are electrically connected with the mains input terminal 101 through the electrical connector 105. The sensor 106 is sleeved on the first electrical connection portion 1051 and is electrically connected with a control board (not shown) of the power distribution device 10.

In the power distribution equipment 10 of the utility model, the power distribution input end 102 and the energy storage input end 103 are electrically connected with the mains input end 101 through the electric connecting piece 105, and the current input by the mains input end 101 can be conducted to the second electric connecting part 1052 through the first electric connecting part 1051 and then be conducted to the power distribution input end 102 and the energy storage input end 103 respectively through the second electric connecting part 1052. By providing the sensor 106 on the first electrical connection 1051, current data of the mains input 101 output to the distribution input 102 and the energy storage input 103 via the first electrical connection 1051 can be obtained. The power distribution equipment 10 of the utility model does not need an external ammeter, can also monitor the power supply condition of the mains supply input end 101 input to each branch, and meets the requirement of a user for conveniently monitoring the electric quantity.

In one embodiment, the sensor 106 includes a sensing portion 1061, and the sensing portion 1061 is provided with a threading hole 10611 therethrough. The first electrical connection portion 1051 passes through the threading hole 10611, and the sensing portion 1061 is configured to electrically couple with the first electrical connection portion 1051.

In this embodiment, the sensor 106 may be a current sensor, and the "current sensor" may be a magnetic sensor, which uses the hall magnetic balance principle to complete sensing of the measured current signal and output the sensed current signal as the information of the required form. The "current sensor" may further be a "hall current sensor" that measures various types of current based on hall effect using the hall magnetic balance principle.

It will be appreciated that by passing the first electrical connection 1051 through the threading aperture 10611, the sensing portion 1061 may be electrically coupled to the first electrical connection 1051. Current data input to the power distribution device 10 by the mains input 101 may be acquired by the sensor 106, which sensor 106 transmits to the control board, which receives the current data. The operator can directly know the current data input to the power distribution equipment 10 through the commercial power input end 101 by looking at the power distribution equipment 10, and the requirement of conveniently monitoring the electric quantity of the user can be met without an external electric meter. In some embodiments, the control panel may interact with a user's terminal device (e.g., a cell phone, tablet, etc.), so that the user may view electricity usage through the terminal device.

It can be appreciated that the sensing portion 1061 may be provided with a magnetic core (not shown), a hall element (not shown), an operational amplifier circuit (not shown), and other necessary elements for implementing the hall magnetic balance principle, and the magnetic core, the hall element, and the operational amplifier circuit may be of known and feasible structures, which are not described herein. The "electrical coupling" refers to that a magnetic field change or a current change generated when a current flows in the first electrical connection portion is sensed by the sensing portion 1061, so that the sensing portion 1061 generates a corresponding electrical signal to obtain corresponding current data.

In one embodiment, the sensor 106 further includes a fixing portion 1062, and the fixing portion 1062 is connected to the sensing portion 1061. The securing portion 1062 includes a positioning post 10612, the positioning post 10612 being disposed toward the body portion 104.

In this embodiment, the positioning posts 10612 are disposed toward the main body 104, such that the positioning posts 10612 can be positioned and connected with a connection structure (not shown) on the main body 104 during assembly. The fixing portion 1062 may further have a positioning slot 10621 formed therethrough, where the positioning slot 10621 may be used to receive a screw, such that the screw passes through the positioning slot 10621 to connect to the main body 104, and the fixing portion 1062 is fixed to the main body 104.

It can be appreciated that the fixing portion 1062 and the sensing portion 1061 may be integrally formed or separately disposed, the fixing portion 1062 is connected to the sensing portion 1061 so that the sensing portion 1061 may be fixed to the main body 104, thereby reducing the probability of shaking of the sensing portion 1061 due to external interference, maintaining the relative stability between the sensing portion 1061 and the electrical connector 105, and improving the sensing accuracy of the sensor 106.

In one embodiment, the main body 104 is provided with two spaced limiting protrusions 1041, and the fixing portion 1062 is disposed between the two limiting protrusions 1041.

It can be appreciated that two limiting protrusions 1041 may be disposed on the main body 104 in the assembly area corresponding to the fixing portion 1062, so that on one hand, an assembler can quickly position the sensor 106 during the assembly process, thereby improving the assembly efficiency; on the other hand, the installed sensor 106 can be limited, the probability of shaking of the sensing part 1061 due to external interference is reduced, the relative stability between the sensing part 1061 and the electric connector 105 is maintained, and the sensing precision of the sensor 106 is improved.

Similarly, the electrical connector 105 has a positioning hole 1053 formed therethrough. The electric connector 105 can be fixedly connected with the main body 104 through a screw, the screw passes through the positioning hole 1053 and is further connected with the main body 104, and the electric connector 105 is pressed on the main body 104 by the screw, so that the electric connector 105 is fixed. The positioning hole 1053 may be formed in at least one of the first electrical connection 1051 and the second electrical connection 1052.

It will be appreciated that the locating holes 1053 may assist an assembler in quickly locating the sensor 106 during assembly, thereby improving assembly efficiency. The installed electric connector 105 is fixed on the main body 104, so that the probability of shaking of the electric connector 105 due to external interference is reduced, the relative stability between the sensor 106 and the electric connector 105 is maintained, and the sensing precision is improved.

In one embodiment, the extending direction of the first electrical connection 1051 is a first direction, and the extending direction of the second electrical connection 1052 is a second direction. The first direction intersects the second direction.

In this embodiment, the utility power input end 101, the power distribution input end 102 and the energy storage input end 103 are arranged at intervals, the utility power input end 101 is disposed between the power distribution input end 102 and the energy storage input end 103, and the power distribution input end 102 and the energy storage input end 103 are disposed on two opposite sides of the first electrical connection portion 1051. Correspondingly, the first electrical connection 1051 for connecting to the mains input 101 and the second electrical connection 1052 for connecting to the power distribution input 102 and the energy storage input 103 should be configured in an intersecting manner, so that the electrical connection 105 can be electrically connected to the mains input 101, the power distribution input 102 and the energy storage input 103 together.

In one embodiment, the second electrical connection 1052 includes a first branch section 10521 and a second branch section 10522 connected. The first branch section 10521 is connected to the distribution input 102 and the second branch section 10522 is connected to the energy storage input 103.

In one embodiment, the first branch section 10521 and the second branch section 10522 are electrically connected to the first electrical connection 1051. The first branch section 10521 and the second branch section 10522 extend to opposite sides of the first electrical connection 1051. The direction of extension of the first branch flow section 10521 intersects the direction of extension of the second branch flow section 10522.

It will be appreciated that the first branch section 10521 is adapted to be connected to the distribution input 102 and the second branch section 10522 is adapted to be connected to the energy storage input 103. The first tributary section 10521 and the second tributary section 10522 are connected with the first electrical connection portion 1051 at the same time, so that the current flowing into the power distribution equipment 10 through the mains input end 101 can be respectively conducted to the power distribution input end 102 and the energy storage input end 103, and the functions of the electrical connection piece 105 for conducting the mains input end 101, the power distribution input end 102 and the energy storage input end 103 are realized.

In this embodiment, the electrical connector 105 is made of copper, and the first electrical connection 1051 and the second electrical connection 1052 are disposed vertically. The copper electrical connector 105 has good electrical conductivity and ductility, is easy to assemble, and is low cost.

It will be appreciated that the electrical connector 105 further includes a protruding portion 1054, and the protruding portion 1054 may be formed on one of the first electrical connector 1051 or the second electrical connector 1052, so as to help an operator distinguish the first electrical connector 1051 from the second electrical connector 1052, thereby further improving the assembly efficiency. In this embodiment, the protrusions 1054 are all provided on the second branch section 10522.

In one embodiment, the utility power input terminal 101 includes a first main input terminal 1011 and a second main input terminal 1012 arranged at an insulation interval, and the distribution input terminal 102 includes a first input branch group 1021 and a second input branch group 1022 arranged at an insulation interval. One electrical connector 105 is electrically connected to the first main input 1011 and the first set of input branches 1021, and the other electrical connector 105 is electrically connected to the second main input 1012 and the second set of input branches 1022, each electrical connector 105 being electrically coupled to a respective one of the sensors 106.

In this embodiment, the first main input 1011 and the second main input 1012 can be electrically connected to the two circuit breakers 107 through a conductive post 1043, respectively.

In this embodiment, the energy storage input terminal 103 may further include a first energy storage sub-input terminal 1031 and a second energy storage sub-input terminal 1032. The first electrical connection 1051 of one electrical connection 105 is connected to the first main input 1011, the first branch 10521 of the electrical connection 105 is connected to the first input branch 1021, and the second branch 10522 of the electrical connection 105 is connected to the first energy storage sub-input 1031. The first electrical connection 1051 of the other electrical connector 105 is connected to the second main input 1012, the first branch section 10521 of the electrical connector 105 is connected to the second input branch set 1022, and the second branch section 10522 of the electrical connector 105 is connected to the second energy storage sub-input 1032. As further shown in connection with fig. 7 and 8, the two electrical connectors 105 may have different shapes.

In this embodiment, the first main input terminal 1011 and the second main input terminal 1012 are insulated from each other, and the first main input terminal 1011 and the second main input terminal 1012 may have the same voltage or different voltages. For example, the first main input 1011 and the second main input 1012 may each have a voltage of 120V. The parts of the plurality of distribution branches are electrically connected with the first main input end 1011 so that the electric appliances under the branches corresponding to the plurality of distribution branches can correspond to 120V voltage; the other portions of the plurality of distribution branches are connected in series with the first primary input 1011 and the second primary input 1012 such that the electrical utility under the branch to which the plurality of distribution branches corresponds can correspond to a voltage of 240V.

In other embodiments, the first main input terminal 1011 and the second main input terminal 1012 may have a voltage of 120V, or the first main input terminal 1011 and the second main input terminal 1012 may have a voltage of 240V, or the first main input terminal 1011 and the second main input terminal 1012 may have a voltage of 110V, or the first main input terminal 1011 and the second main input terminal 1012 may have a voltage of 220V. That is, the voltages at the first main input terminal 1011 and the second main input terminal 1012 may be the same or different, and it is necessary to ensure that the input terminal and the second main input terminal 1012 have corresponding conduction capabilities.

It can be understood that by providing the first main input end 1011 and the second main input end 1012 which are insulated from each other, and making the first main input end 1011 and the second main input end 1012 electrically connected to different power distribution branches, a user can select a suitable working voltage according to the power consumption voltage requirement of the electric appliance, so as to further improve the adaptability of the power distribution device 10 and the external electric appliance.

Hereinabove, the specific embodiments of the present utility model are described with reference to the accompanying drawings. However, those of ordinary skill in the art will appreciate that various modifications and substitutions can be made to the specific embodiments of the utility model without departing from the scope thereof. Such modifications and substitutions are intended to be included within the scope of the present utility model.

Claims (10)

1. A power distribution apparatus comprising a utility power input, a power distribution input, and an energy storage input, the power distribution apparatus further comprising:

the electric connecting piece comprises a first electric connecting part and a second electric connecting part, the first electric connecting part is connected with the mains supply input end, the second electric connecting part is respectively connected with the power distribution input end and the energy storage input end, and the power distribution input end and the energy storage input end are electrically connected with the mains supply input end through the electric connecting piece;

and the sensor is sleeved on the first electric connection part and is electrically connected with the control panel of the power distribution equipment.

2. The electrical distribution device of claim 1, wherein the second electrical connection comprises a first branch segment and a second branch segment connected, the first branch segment being connected to the electrical distribution input, the second branch segment being connected to the energy storage input.

3. The electrical distribution device of claim 2, wherein the first branch segment and the second branch segment are each electrically connected to the first electrical connection, the first branch segment and the second branch segment extending toward opposite sides of the first electrical connection, respectively.

4. The electrical distribution apparatus of claim 2, wherein the direction of extension of the first branch segment intersects the direction of extension of the second branch segment.

5. The electrical distribution device of any of claims 1-4, wherein the direction of extension of the first electrical connection is a first direction and the direction of extension of the second electrical connection is a second direction, the first direction intersecting the second direction.

6. The electrical distribution device of any one of claims 1 to 4, wherein the sensor comprises an inductive portion having a threading aperture therethrough, the first electrical connection passing through the threading aperture, the inductive portion being configured to electrically couple with the first electrical connection.

7. The power distribution device of claim 6, wherein the sensor further comprises a fixing portion, the fixing portion is connected with the sensing portion, the power distribution device further comprises a main body portion, two spaced limiting protrusions are arranged on the main body portion, and the fixing portion is arranged between the two limiting protrusions.

8. The electrical distribution apparatus of claim 7, wherein the sensing portion is further provided with a locating post disposed toward the body portion.

9. The electrical distribution device of any of claims 1 to 4, wherein the electrical connector is provided with a locating hole.

10. The electrical distribution device of any of claims 1-4, wherein the mains input comprises first and second main inputs arranged at an insulating interval, the electrical distribution input comprises first and second groups of input branches arranged at an insulating interval, one of the electrical connectors is electrically connected to the first main input and the first group of input branches, the other electrical connector is electrically connected to the second main input and the second group of input branches, and each of the electrical connectors is electrically coupled to one of the sensors, respectively.