WO2017211324A1 - Adapter, portable power system, and power system - Google Patents

Abstract

An adapter (10; 40) comprises: an inverter configured to convert a direct current output by a battery pack (20, 30) to an alternating current; a rectifier configured to convert an alternating current to a direct current that can charge a battery pack; a housing (11; 41) configured to accommodate the inverter or/and the rectifier; an alternating current input interface (12; 42) configured to connect the adapter to an alternating current source; an alternating current output interface (13, 14; 43, 44) configured to cause the adapter to output an alternating current; and an adapter interface (17, 18; 47, 48) configured to be detachably connected to a battery pack that can power an electric tool, in which the alternating current input interface is connected to the rectifier, and the alternating current output interface is connected to the inverter. A portable power system and a power system comprise the adapter. The adapter can continuously provide power. The portable power system and the power system can operate for a long time.

Description

Adapter, portable power system and power system Technical field

The present invention relates to a power supply, and more particularly to an adapter, a portable power system, and the electrical energy system comprising the same.

Background technique

With the development of battery technology, power tools are gradually replacing engine tools. In order to achieve the working effect and endurance time of the engine work, the rated power and capacity of the battery pack are also increasing.

Working and traveling outdoors often requires AC power to power some equipment. Traditional portable power supplies are often powered by internal battery packs. Once the power of the battery pack is exhausted, AC power cannot be continuously supplied.

Summary of the invention

In order to solve the deficiencies of the prior art, it is an object of the present invention to provide a portable power source capable of continuously providing alternating current.

In order to achieve the above objectives, the present invention adopts the following technical solutions:

A portable electric energy system comprising: a battery pack capable of supplying at least one power tool; an adapter for outputting or outputting electrical energy to the battery pack; wherein the battery pack comprises: a battery core for storing electrical energy a first housing for accommodating the battery core; the adapter includes: an inverter for converting a direct current of the output of the battery pack into an alternating current; a rectifier for converting the alternating current into a direct current charged by the battery pack; the second housing Used to house the inverter or / and rectifier; the battery pack is detachably connected to the adapter.

Further, the adapter further includes: an alternating current input interface for connecting the adapter to the alternating current; and an alternating current output interface for causing the adapter to output alternating current; wherein the alternating current input interface is connected to the rectifier; and the alternating current output interface is connected to the inverter.

Further, the output voltage of the AC output interface is equal to the access voltage of the AC input interface.

Further, the adapter further includes: a direct current output interface for causing the adapter to output direct current; and an output voltage of the direct current output interface is lower than a rated voltage of the battery pack.

Further, the adapter further includes: a plurality of direct current output interfaces for causing the adapter to output a direct current lower than a rated voltage of the battery pack; wherein the voltage of one of the direct current output interfaces is lower than the voltage of the other of the direct current output interfaces.

Further, the adapter further includes: a direct current input interface for connecting the adapter to the direct current charged for the battery pack.

Further, the adapter further includes: a display for displaying information of the adapter.

Further, the adapter further includes: a player for playing video or music.

Further, the portable power system further includes: a photovoltaic panel for converting solar energy into electrical energy to charge or input the battery pack to the adapter.

Further, the adapter further includes: an illumination lamp capable of using the power of the access adapter for illumination.

Further, the portable power system has a plurality of battery packs, one of which can charge another battery pack through the adapter.

Further, the portable power system has a plurality of battery packs having different rated voltages, and one of the battery packs can charge another battery pack through the adapter.

Further, the adapter further includes: a wireless charging device for wirelessly charging the other powered devices with the electrical energy of the battery pack.

Further, the adapter further includes: a wireless communication device for wirelessly communicating the adapter with the battery pack, other adapters, and other communication devices.

Further, the adapter further includes: a projector for projecting an image.

Further, the rated voltage of the battery pack is greater than or equal to 30V and less than or equal to 350V.

Further, the weight of the battery pack is greater than or equal to 1 kg and less than or equal to 10 kg.

Further, the power capacity of the battery pack is greater than or equal to 100 Wh and less than or equal to 2000 Wh.

Further, the ratio of the total power of all the battery packs that the adapter can combine to the total weight of the portable power system ranges from 7 Wh/kg to 200 Wh/kg.

Further, the ratio of the total mass of all the battery packs that the adapter can combine to the total weight of the portable power system ranges from 0.15 to 0.90.

Further, the ratio of the voltage of the battery pack to the voltage of the alternating current output by the adapter ranges from 0.07 to 1.5.

Further, the ratio of the voltage of the battery pack to the voltage of the direct current output by the adapter is defined as a straight-to-voltage ratio; the ratio of the straight-varying voltage ranges from 0.5 to 32.

Further, the adapter includes: an adapting interface for detachably connecting the battery pack to the adapter; the adapting interface includes: an electrical connection terminal for electrically connecting with the battery core of the battery pack; and a connection structure for The first housing and the second housing are connected; the electrical connection terminals are connected to the inverter and the rectifier.

Further, the adapter includes: two or more adapter interfaces for connecting the battery pack to the adapter; the two adapter interfaces are disposed on opposite sides of the second housing.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; the second housing is provided with: a receiving groove formed on one side of the second housing and recessed toward the opposite side; the fitting interface Set in the receiving slot.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; the second housing is provided with: a receiving groove formed on one side of the second housing and recessed toward the opposite side; the fitting interface The receiving slot is disposed in the receiving slot to at least partially receive the battery pack in the receiving slot.

Further, the adapter includes: a handle for the user to hold; two or more adapter interfaces for connecting the battery pack to the adapter; the two adapter interfaces are disposed on opposite sides of the second housing The battery is packaged to be balanced with respect to the handle when attached to the adapter interface on both sides.

Further, the adapter includes: two handles for the user to hold; an adapter interface for connecting the battery pack to the adapter; two handles are disposed on both sides of the adapter interface to allow the battery pack to be connected to the adapter The interface is located between the two handles.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; a support base for supporting the battery pack when the battery pack is connected to the adapter interface; the adapting interface includes: an electrical connection terminal for the battery The battery core of the package constitutes an electrical connection; the connection structure is configured to connect the first housing and the second housing; the support base includes at least one support portion beyond the connection structure to enable the battery pack to be connected to the adapter interface when the battery pack is The center of gravity is outside the connection structure and above the support.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; a support base for supporting the battery pack when the battery pack is connected to the adapter interface; the adapting interface includes: an electrical connection terminal for the battery The battery core of the package constitutes an electrical connection; the connection structure is configured to connect the first housing and the second housing; the support base includes at least one support portion beyond the connection structure to enable the battery pack to be connected to the adapter interface when the battery pack is The center of gravity is above the support.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; a support base for supporting the battery pack when the battery pack is connected to the adapter interface; and the second housing is provided with: a receiving slot formed in the first One side of the two housings is recessed toward the opposite side; the support seat is formed at the bottom of the receiving groove and protrudes outwardly from the receiving groove.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; a support base for supporting the battery pack when the battery pack is connected to the adapter interface; and the second housing is provided with: a receiving slot formed in the first One side of the two housings is recessed toward the opposite side; the mating interface is disposed in the receiving slot to at least partially receive the battery pack in the receiving slot; the support base is at least partially located below the mating interface and recessed in the receiving slot The opposite direction protrudes from the adapter interface.

Further, the adapter includes: a handle for the user to hold; an adapter interface for connecting the battery pack to the adapter; a support base for supporting the battery pack when the battery pack is connected to the adapter interface; the handle and the support base They are respectively disposed on opposite sides of the adapter interface.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; the adapting interface includes: a connecting structure for connecting the first housing and the second housing; the connecting structure comprises: a guide rail for the battery The package is slidably connected to the adapter.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; the second housing is provided with: a receiving groove formed on one side of the second housing and recessed toward the opposite side; the fitting interface The method includes a connection structure for connecting the first housing and the second housing, and the connection structure includes: a guide rail for slidably connecting the battery pack to the adapter in a direction in which the receiving slot extends.

Further, the adapter is provided with a mid-plane and further comprises: two or more adapter interfaces for connecting the battery pack to the adapter in a plane-symmetrical manner; the adapter interface comprises: a connection structure, Connecting the first housing and the second housing; the connecting structure comprises: a guide rail for slidably connecting the battery pack to the adapter in a direction parallel to the middle facet.

Further, the adapter further includes: a fan for cooling components inside the adapter; an adapting interface for connecting the battery pack to the adapter; the adapting interface being disposed at a front side of the second housing; and the second housing at least The left side or the right side forms a vent hole through which the airflow generated by the fan passes; the fan is disposed inside the second casing.

Further, the adapter further includes: a fan for cooling components inside the adapter; an adapting interface for connecting the battery pack to the adapter; the adapting interface being disposed at a front side of the second housing; the fan being disposed in the adapter and located Adapt the left or right side of the interface.

Further, the adapter further includes: a fan for generating an air flow; a circuit board disposed inside the second casing; a semiconductor device connected to the circuit board; and a heat sink connected to the semiconductor device to cause the airflow generated by the fan to flow through the heat dissipation Device.

Further, the adapter further includes: a fan for cooling components inside the adapter; an adapter interface, For connecting the battery pack to the adapter; the adapter interface is disposed on the front side or the rear side of the second housing; and the second housing forms an air inlet hole for the airflow generated by the fan to flow into the second housing at least on the left side thereof The second housing forms an air outlet for the airflow generated by the fan to flow into the interior of the second housing at least on the right side thereof.

Further, the adapter further includes: a fan for cooling components inside the adapter; an adapting interface for connecting the battery pack to the adapter; the adapting interface being disposed at a front side or a rear side of the second housing; the second housing Forming, at least on the left side thereof, an air inlet hole for the airflow generated by the fan to flow into the interior of the second casing; the second casing forming an air outlet hole for the airflow generated by the fan to flow into the interior of the second casing at least on the right side thereof; the air inlet And the air outlet is staggered in the up and down direction.

Further, the adapter further includes: a fan that can be driven to rotate about a pivot axis; a circuit board disposed inside the second housing; a semiconductor device connected to the circuit board; a heat sink connected to the semiconductor device; and the circuit board substantially Parallel to the pivot axis of the fan; the pivot axes of the heat sink and fan are on the same side of the board.

Further, the adapter further includes: a fan that can be driven to rotate about a pivot axis; two or more adapter interfaces for connecting the battery pack to the adapter; and a circuit board disposed inside the second housing; The semiconductor device is connected to the circuit board; the heat sink is connected to the semiconductor device; the pivot axis of the fan is disposed between the two adapter interfaces; the heat sink is located between the two adapter interfaces.

Further, the adapter further includes: two or more adapter interfaces for connecting the battery pack to the adapter; a fan that can be driven to rotate about a pivot axis; and a circuit board disposed inside the second housing; a semiconductor device connected to the circuit board; a heat sink connected to the semiconductor device; the adapter interface being disposed on the front side or the rear side of the second housing; the pivot axis of the fan being disposed between the two mating interfaces and capable of generating Airflow flowing from left to right.

Further, the adapter further includes: two or more adapter interfaces for connecting the battery pack to the adapter; the fan can be driven to rotate about a pivot axis; and the plurality of circuit boards are disposed inside the second housing a semiconductor device connected to the circuit board; a heat sink connected to the semiconductor device; an adapter interface disposed on a front side or a rear side of the exterior of the second housing; at least one of the circuit boards disposed on a front side of the interior of the second housing Or the back side, the heat sink is located between the two boards.

Further, the adapter further includes: an adapting interface for connecting the battery pack to the adapter; an alternating current input interface for connecting the adapter to the alternating current; the adapting interface being disposed on the front side or the rear side of the adapter; and the alternating current input interface being disposed on the Left or right side of the adapter.

Further, the adapter further includes: an adapting interface for connecting the battery pack to the adapter; an alternating current output interface for causing the adapter to output alternating current; the adapting interface being disposed on the front side or the rear side of the adapter; and the alternating current output interface being disposed on the adapter Left or right side.

Further, the adapter further includes: an adapting interface for connecting the battery pack to the adapter; a direct current output interface for causing the adapter to output direct current; the adapting interface being disposed on the front side or the rear side of the adapter; and the direct current output interface being disposed on the adapter Left or right side.

Further, the adapter further includes: an adapting interface for connecting the battery pack to the adapter; an operation interface for the user to operate the adapter; the adapting interface is disposed on the front side or the rear side of the adapter; the operation interface is disposed on the left side of the adapter, Right or top side.

Further, the adapter further includes: an adapting interface for connecting the battery pack to the adapter; a display interface for displaying information of the portable power system; the adapting interface being disposed at a front side or a rear side of the adapter; and the display interface being disposed at the adapter Left, right or top side.

Further, the adapter further includes: a protection frame disposed outside the two opposite sides of the second housing.

Further, the protection frame further includes: a base disposed at a bottom of the second housing; a top seat disposed at a top of the second housing; and a support post connected to the base and the top seat, respectively.

Further, the adapter further includes: a damping device for buffering an impact between the protection frame and the second housing.

Further, the damper device comprises: a flexible member disposed between the base and the second housing or between the top seat and the second housing.

Further, the damping device comprises: an elastic member disposed between the base and the top seat.

Further, the elastic member is housed in the support column.

Further, a protection frame for protecting the second casing; an adapter interface for connecting the battery pack to the adapter; the protection frame further comprising: a base for protecting the bottom of the second casing; and a top seat for protecting a top portion of the second housing; the support columns are respectively connected to the base and the top seat; the adapter interface is disposed on the front side or the rear side of the second housing to connect the battery pack to the adapter interface between the two support columns .

Further, a protection frame for protecting the second casing; an adapter interface for connecting the battery pack to the adapter; the protection frame further comprising: a base for protecting the bottom of the second casing; and a top seat for protecting a top portion of the second housing; the support columns are respectively connected to the base and the top seat; the top seat is provided with or connected with a handle for the user to hold; the adapter interfaces are respectively located at two sides of the handle.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; a protection frame for protecting the second housing; the adapting interface comprising: a guide rail for slidably connecting the battery pack to the adapter; The frame also includes a support post that is formed generally parallel to the direction of the rail.

Further, the adapter includes: an adapting interface for connecting the battery pack to the adapter; a protection frame, providing an outer side of the second housing; a fan disposed inside the second housing; and the protection frame comprising: a plurality of support columns disposed at The battery pack connected to the adapter interface is placed between them; the fan is placed between the two support columns.

An adapter comprising: an inverter for converting a direct current of an output of a battery pack into an alternating current; a rectifier for converting alternating current into a direct current charged by the battery pack; and a housing for housing the inverter or/and the rectifier The AC input interface is used to connect the adapter to the AC power; the AC output interface is used to enable the adapter to output AC power; the adapter interface is used to detachably connect a battery pack capable of supplying power to a power tool; wherein, the AC input The interface is connected to the rectifier; the AC output interface is connected to the inverter.

An electrical energy system comprising: a DC power tool comprising a power device; a battery pack detachably connected to and powered by the DC power tool; and an adapter for outputting or outputting power to the battery pack The battery pack includes: a battery core for storing electrical energy; a first housing for accommodating the battery core; the adapter includes: an inverter for converting a direct current of the output of the battery pack into an alternating current; and a rectifier for The alternating current is changed to a direct current charged by the battery pack; the second housing is for housing the inverter or/and the rectifier; and the battery pack is detachably connected to the adapter.

An electrical energy system comprising: a DC power tool including a power device; an AC power tool including a motor; a battery pack detachably connected to and powered by the DC power tool; and an adapter for outputting the battery pack The electrical energy or the electrical energy is input to the battery pack; wherein the battery pack comprises: a battery core for storing electrical energy; a first housing for accommodating the battery core; and the adapter comprising: an inverter for directing the output of the battery pack Becomes alternating current; a rectifier for converting alternating current into direct current for charging a battery pack; a second housing for housing an inverter or/and a rectifier; an alternating current output interface for outputting alternating current to an alternating current power tool; The detached connection to the adapter; the AC output interface is connected to the inverter.

An electrical energy system comprising: a battery pack; a power tool comprising a motor; a first adapter for causing the battery pack to output electrical energy or input electrical energy to the battery pack; and a second adapter for causing the battery pack to output electrical energy or to enable electrical energy Input to the battery pack; the battery pack includes: a battery core for storing electrical energy; a first housing for accommodating the battery core; and a first adapter including: a first inverter for changing a direct current of the output of the battery pack Pay a first rectifier, the direct current for changing the alternating current into a battery pack; the second adapter includes: a second inverter for converting the output of the battery pack into alternating current; and a second rectifier for making The alternating current becomes a direct current charged by the battery pack; the battery pack is detachably connected to the first adapter and/or the second adapter; the first adapter and the second adapter can collectively power the power tool.

The invention is advantageous in that the adapter is capable of continuously providing alternating current. Easy to carry.

DRAWINGS

1 is a perspective view of an exemplary portable power system;

Figure 2 is a top plan view of the portable power system shown in Figure 1;

3 is a perspective view of the portable electric energy system shown in FIG. 1 in a state in which the battery pack is removed;

Figure 4 is an enlarged schematic view showing the partial structure shown in Figure 3;

Figure 5 is a perspective view of the battery pack in the portable electric energy system shown in Figure 1;

Figure 6 is a schematic exploded view of the portable electrical energy system shown in Figure 1;

7 is a perspective view of another example portable power system;

Figure 8 is a top plan view of the portable power system shown in Figure 7;

Figure 9 is a perspective view of the portable electric energy system shown in Figure 7 in a state in which the battery pack is removed;

Figure 10 is a schematic illustration of one side of the portable power system shown in Figure 7;

Figure 11 is a schematic illustration of the other side of the portable power system shown in Figure 7;

Figure 12 is a schematic exploded view of some components of the portable power system shown in Figure 7;

Figure 13 is an enlarged plan view showing a portion of the structure of Figure 12;

Figure 14 shows an electrical energy system as an example;

Figure 15 shows a combination of a portable power system and a photovoltaic panel;

Figure 16 shows a combination of a battery and an adapter for an automobile;

Figure 17 shows another example of an electrical energy system.

detailed description

The present invention will be specifically described below in conjunction with the accompanying drawings and specific embodiments.

The portable power system 100 shown in FIG. 1 includes an adapter 10 and two battery packs 20, 30.

The battery pack 20 or the battery pack 30 may be the same battery pack or a different battery pack, and both of them can supply power to a DC power tool.

Specifically, as shown in FIG. 5, the battery pack 20 includes a battery core 21 and a first housing 22. Battery 21 It is housed in the first housing 22.

The battery cell 21 is used to store energy, which can be repeatedly charged and discharged. The battery cell 21 can be selected from a lithium ion battery. The first housing 22 is for accommodating the battery cells 21 and other components in the battery pack 20, and the first housing 22 is formed with a joint portion 23 through which the battery pack 20 can be coupled to a power tool.

The battery pack 20 further includes a plurality of electrode connection terminals for at least electrically connecting the battery core 21 to an external circuit. For example, it is electrically connected to a charging circuit in a circuit or a charger for driving a motor in a power tool.

The battery pack 20 may also include other types of connection terminals, such as communication terminals for communication, and communication terminals for signal interaction.

In addition, the battery pack 20 may also include a circuit board, a controller, and some corresponding detectors. The circuit board is mainly used to construct the circuit in the battery pack 20. The controller mainly controls the battery pack 20. The detector is mainly used to detect some electrical parameters and physical parameters of the battery pack 20, such as current, voltage or the interior of the battery pack 20. The temperature and so on. Specifically, the circuit board, the controller, and the detector constitute a circuit that allows the battery pack 20 to have an over-discharge protection or an over-charge protection function to prevent over-discharge or over-charging, and to enable the battery pack 20 to be wired with other external devices. Or wireless communication.

Specifically, the rated voltage of the battery pack 20 is 30 V or more and 350 V or less. More specifically, the rated voltage of the battery pack 20 ranges from 30V to 50V, 50V to 85V, 85V to 100V, 100V to 200V or 200V to 350V.

The weight of the battery pack 20 is 1 kg or more and 10 kg or less. More specifically, the weight of the battery pack 20 ranges from 1 kg to 2 kg, 2 kg to 2.5 kg, 2.5 kg to 3 kg, 3 k to 4 kg, 4 kg to 5 kg, 5 kg to 6 kg, 6 kg to 7 kg, 7 kg to 8 kg, 8kg to 9kg, 9kg to 10kg.

The battery pack 20 has a power of 100 Wh or more and 2000 Wh or less. Specifically, the battery pack 20 has a power range of 100 Wh to 150 Wh, 150 Wh to 200 Wh, 200 Wh to 250 Wh, 200 Wh to 300 Wh, 300 Wh to 400 Wh, 400 Wh to 450 Wh, 450 Wh to 500 Wh, 500 Wh to 600 Wh, and 700 Wh to 800 Wh. 800Wh to 900Wh, 900Wh to 1000Wh, 1000Wh to 1100Wh, 1100Wh to 1200Wh, 1200Wh to 1300Wh, 1300Wh to 1400Wh, 1400Wh to 1500Wh, 1500Wh to 1600Wh, 1600Wh to 1700Wh, 1700Wh to 1800Wh, 1800Wh to 1900Wh, 1900Wh to 2000Wh.

The adapter 10 can connect the battery pack 20 and the battery pack 30 described above so that they can pass through The adapter 10 shows electrical energy or acquires electrical energy. The battery pack 20 and the battery pack 30 may be separately connected to the adapter 10 or may be connected to the adapter 10 in common.

The adapter 10 includes a second housing 11 that can form a portion that fits the joint 23 of the battery pack 20 to enable the battery pack 20 to be detachably coupled to the adapter 10.

The adapter 10 also includes an inverter and a rectifier. The inverter can convert the direct current outputted by the battery pack connected to the adapter 10 into alternating current; the rectifier can convert the alternating current that the adapter 10 is connected into the direct current that can charge the battery pack. Both the inverter and the rectifier are constituted by respective circuit boards and circuit components, and the circuit boards and circuit components constituting the inverter and the rectifier are housed in the accommodating chamber formed by the second casing 11.

The adapter 10 also includes an alternating current input interface that enables the adapter 10 to be connected to alternating current in the electrical grid. Specifically, the AC input interface can be configured as the power plug 12 as shown in FIG. 1 , which has the advantages of ensuring electrical safety; or can be configured as a general AC interface (the specific interface can be similar to the power socket 13 ), thereby It is convenient for users to select power cables of different lengths for transfer.

The adapter 10 can charge the connected battery pack through the connected alternating current; as a specific solution, the alternating current input interface is electrically connected to the rectifier, so that the alternating current input from the alternating current input interface is changed to direct current and the battery pack is charged.

The adapter 10 also includes an alternating current output interface; it can be used to output alternating current so that the electrical energy system 100 can function as an AC power source. As a specific solution, the power source of the AC output interface may be the power stored in the battery pack connected to the adapter 10, or the power accessed by the adapter 10 from the battery, such as the AC power grid introduced from the AC input interface. Electrical energy. The AC output interface can be constructed in the form of power outlets 13, 14 as shown in Figure 1. The power outlets 13 and 14 are preferably designed to have the same specifications as the sockets of the local general grid output electrical energy, so that the electrical energy system 100 can be general. The AC is powered by electrical equipment. The power outlets 13, 14 may be disposed on the same side of the adapter 10 or on the opposite side of the adapter 10.

The adapter 10 can use the battery pack power to which it is connected and output AC power through the AC output interface. As a specific solution, the AC output interface is at least electrically connected to the inverter. The direct current from the battery pack is converted to alternating current through the inverter and then output to the alternating current output interface.

As a solution, the output voltage of the AC output interface is equal to the access voltage of the AC input interface.

The adapter 10 also includes a direct current output interface for causing the adapter 10 to output direct current. Specifically In other words, the DC output interface can be configured as a 5V USB interface 15 as shown in FIG. 1, or can be configured as a 12V vehicle power interface 16 as shown in FIG. 1; of course, the DC output interface can also be configured as other Form, output other voltages such as 19V, 36V. As a solution, the voltage of the DC output interface should be lower than the rated voltage of the battery pack. When there are multiple DC output interfaces, the voltage of one of the DC output interfaces is less than the voltage of the other DC output interface.

As an extension, the power system 100 further includes an adapter device, the one end port of the adapter device is designed to be compatible with the DC output interface of the adapter 10, such as a plug designed as a 12V vehicle power supply, and the other end is designed as a fake battery pack. The form, that is, the port with the battery pack but no battery, allows the DC power supply from the adapter 10 to be obtained by the DC power tool using the battery pack through the switching device.

As an extension, the adapter 10 can also include a DC input interface for connecting the adapter 10 to DC power. The adapter 10 can charge the battery pack from the direct current that is external to its battery pack, and can also be used by other powered devices in the power system 100. As shown in FIG. 15, the user can use the photovoltaic panel 80 to convert the direct current generated by the solar energy from the DC input interface input adapter 10 to charge the battery pack to which the adapter 10 is connected. As shown in FIG. 16, the user can use the battery 90 of the car to connect to the adapter 10 through the DC input interface, thereby charging the battery pack connected to the adapter 10. The user can also activate the engine of the car to idle the car battery 90. Thus, the battery pack in the electrical energy system 100 can always be charged as long as the vehicle has fuel. Of course, the user can use the DC output interface of the adapter 10 to charge the battery 90 of the car to solve the problem that the car cannot be started because the battery 90 is emptied.

The DC input interface can also be constructed as a USB interface 15 or 12V interface as shown in FIG.

As an alternative, the electric energy system 100 has a plurality of battery packs, which may be battery packs with the same rated voltage or battery packs with different rated voltages; the adapter 10 enables one of the batteries to have a higher voltage or/and a power amount. The battery pack charges another battery pack having a lower voltage or/and power; of course, the adapter 10 passes the internal circuit to make the battery pack having a lower voltage or/and a lower voltage or higher. Charge the battery pack with the battery.

When the adapter 10 charges one battery pack for another battery pack, the interface to which the battery pack is attached can also function as a DC input interface.

As an alternative, the adapter 10 further includes a wireless charging device including a charging coil and a wireless charging circuit, the wireless charging circuit causing the charging coil to pass current, thereby generating The magnetic field; the consumer that needs to be charged can receive the coil, or receive power through an adapter with a receiving coil that generates a current through the receiving coil to effect the transmission of electrical energy. This allows the adapter 10 to which the battery pack is attached to be wirelessly charged when it is used as a power source. The wireless charging device can be powered by the AC power source that is connected to the adapter 10 or by the DC power supplied by the battery pack to which the adapter 10 is connected.

As an alternative, the adapter 10 also includes a wireless communication device that can be used to wirelessly communicate the adapter 10 with a battery pack, other adapters, or other wireless communication device. As a specific solution, the wireless communication device can be used as a wireless router of a local area network, which can directly access the Internet to enable other wireless communication devices in the local area network to access the Internet, and can also access through a communication device. The wireless communication device of the Internet enables other wireless communication devices in the local area network to access the Internet. Of course, the wireless communication device in the adapter 10 can also enable data communication only by each wireless communication device in the local area network; the wireless communication device can adopt Bluetooth, Wireless communication is implemented by means of WiFi, NFC, ZigBee, and the like.

As can be seen from the above description, the adapter 10 of the electric energy system 100 can be used as a charger to charge a battery pack connected to the adapter 10, or as a conversion device to output alternating current using the electrical energy stored in the battery pack. The battery pack to which the adapter 10 is connected may be the same battery pack or a different battery pack. When the adapter 10 is used as a charger, it can output different charging voltages for different battery packs; when the adapter 10 is used as a switching device, it can also discharge different battery packs at the same time to output electric energy converted into alternating current.

As an alternative, the ratio of the total power of all the battery packs that the adapter 10 can combine to the total weight of the portable power system 100 ranges from 7 Wh/kg to 200 Wh/kg.

In some embodiments, the ratio of the total amount of all battery packs that the adapter 10 can combine to the total mass of the portable power system 100 ranges from 7 Wh/kg to 20 Wh/kg, 21 Wh/kg to 40 Wh/kg, 41Wh/kg to 60Wh/kg, 60Wh/kg to 80Wh/kg, 80Wh/kg to 100Wh/kg, 100Wh/kg to 120Wh/kg, 120Wh/kg to 140Wh/kg, 140Wh/kg to 160Wh/kg, 160Wh/ Kg to 180 Wh/kg, 180 Wh/kg to 20 Wh/kg.

In other embodiments, the ratio of the total power of all battery packs that the adapter 10 can combine to the total mass of the portable power system 100 ranges from 7 Wh/kg to 10 Wh/kg, 15 Wh/kg to 20 Wh/kg. 20Wh/kg to 30Wh/kg, 30Wh/kg to 40Wh/kg, 40Wh/kg to 55Wh/kg, 55Wh/kg to 60Wh/kg, 60Wh/kg to 70Wh/kg, 70Wh/kg to 75Wh/kg, 75Wh /kg to 80Wh/kg, 80Wh/kg to 90Wh/kg, 90Wh/kg to 100Wh/kg, 100Wh/kg to 106Wh/kg, 20Wh/kg to 75Wh/kg, 30Wh/kg to 70Wh/kg, 20Wh/kg to 100Wh/ Kg.

The ratio of the total mass of all battery packs that the adapter 10 can combine to the total weight of the portable power system ranges from 0.15 to 0.90.

In some embodiments, the ratio of the total mass of all battery packs that the adapter 10 can incorporate to the total weight of the portable power system ranges from 0.15 to 0.20, 0.20 to 0.25, 0.25 to 0.30, 0.30 to 0.35, 0.35. To 0.40, 0.40 to 0.45, 0.45 to 0.50, 0.50 to 0.55, 0.55 to 0.60, 0.60 to 0.65, 0.65 to 0.70, 0.70 to 0.75, 0.75 to 0.80, 0.80 to 0.85, 0.85 to 0.90.

In other embodiments, the ratio of the total mass of all battery packs that the adapter 10 can combine to the total weight of the portable power system ranges from 0.18 to 0.70, 0.18 to 0.30, 0.30 to 0.40, and 0.40 to 0.50. 0.50 to 0.70, 0.20 to 0.70, 0.30 to 0.60, 0.40 to 0.50, 0.50 to 0.70.

The ratio of the voltage of the battery pack to the voltage of the alternating current output by the adapter 10 ranges from 0.07 to 1.5.

In some embodiments, the ratio of the voltage of the battery pack to the voltage of the alternating current output by the adapter 10 ranges from 0.16 to 1.5, 0.07 to 0.10, 0.10 to 0.20, 0.20 to 0.30, 0.30 to 0.40, and 0.50 to 0.60. , 0.70 to 0.80, 0.80 to 0.90, 0.90 to 1.00, 1.00 to 1.10, 1.10 to 1.20, 1.20 to 1.30, 1.30 to 1.40, 1.40 to 1.50.

The ratio of the voltage of the battery pack to the voltage of the direct current output by the adapter 10 ranges from 0.5 to 32.

In some embodiments, the ratio of the voltage of the battery pack to the voltage of the direct current output by the adapter 10 ranges from 0.5 to 8.2, 3.6 to 31.2, and 1.5 to 13.

In other embodiments, the ratio of the voltage of the battery pack to the voltage of the direct current output by the adapter 10 ranges from 0.5 to 1, 1 to 3, 3 to 4, 4 to 5, 5 to 8, 8 to 9, 9 to 11, 11 to 12, 12 to 14, 14 to 17, 17 to 19, 19 to 20, 20 to 25, 25 to 30, 30 to 32.

As shown in FIGS. 3 through 5, the adapter 10 includes an adapter interface 17 and an adapter interface 18.

As shown in Figures 4 and 5, the adapter interface 18 includes a plurality of electrical connection terminals 181, 182, 183 and 184 for connection to corresponding terminals in the battery pack such that the adapter 10 is electrically coupled to the battery pack for transmission. Electrical energy or signal. Specifically, the electrical connection terminals 181, 184 are for connection with the positive and negative terminals of the battery pack; they are at least electrically connected to the inverter or rectifier circuit in the adapter 10.

The adapter interface 18 also includes a connection structure 185 that enables the housing of the battery pack to be detachably coupled to the housing of the adapter. In particular, the connection structure 185 includes two rails 185a and 185b. The guide rails 185a and 185b are capable of guiding the battery pack 30 to slidably connect the battery pack 30 to the adapter 10. The guide rails 185a and 185b are respectively formed on both sides of a bump 186 which protrudes forward with respect to the periphery, and the electrical connection terminals 181, 182, 183 and 184 are disposed at the top end of the bump 186; the bump 186 includes two portions which are distributed front and rear: The rail portion 186a and the boss portion 186b, the rails 185a and 185b are formed on the right and left sides of the rail portion 186a, and the boss portion 186b further protrudes forward from the rail portion 186a.

Since the battery pack 30 and the battery pack 20 are the same battery pack, the structure in which the battery pack 30 is engaged with the guide rails 185a and 185b will be described below by referring to the corresponding structure of the battery pack 20.

As shown in FIG. 5, the joint portion 23 of the battery pack 20 is formed with a recess 231 that can be engaged with the bump 186, and the recess 231 is provided with an electrical interface 24 of the battery pack 20, the electrical interface 24 comprising: a terminal interface 241, 242, 243, and 244. The electrical connection terminals of the adapter 10 can be electrically connected to the terminals inside the battery pack 20 by being inserted into corresponding terminal interfaces. Guide structures 231a and 231b that cooperate with the guide rails are respectively provided on both sides of the recess 231.

The battery pack 20 or 30 can be inserted into the adapter 10 substantially in the vertical direction of FIG. 4, the cooperation of the rail and the guide structure, and the engagement of the bumps with the recess limits the movement of the battery pack relative to the adapter 10 in the front, rear, and left and right directions, and thus the adapter 10 As long as the battery pack is limited in the vertical direction, the battery pack and the adapter can be integrated. The adapter 10 can form a stop surface stop at the bottom of the battery pack. The battery pack can be moved downward along the insertion and removal direction, and a movable hook can be set to lock the battery pack when the battery pack is inserted into the designated position so that the battery pack cannot be inserted. The direction is reversed back.

As an alternative, it is of course also possible to form a structure similar to the recess 231 by the adapter, and a structure similar to the bump 186 is formed by the battery pack, but this may increase the size of the adapter.

The adapter interface 18 is used to detachably connect the battery pack 30 (the battery pack 30 is not shown in FIG. 3 to show the adapter interface 18, and may be referred to the battery pack 30 shown in FIGS. 1 and 2). The adapter interface 17 is for detachably connecting the battery pack 20 to the adapter 10.

This has the advantage that the circuit boards and electronic components connected to the electrical connection terminals in the adapter interfaces 17 and 18 can be placed between them to facilitate wiring and heat dissipation.

Of course, the adapter interface can also be opposite to other opposite sides, such as the upper and lower sides, the left and right sides, and other orientations. When there are more battery packs, multiple adapter interfaces can be set on one side or on the left and right. The adapter interface for connecting the battery pack is set in the right and front directions.

In the present specification, the up, down, left, and right front and back are used to facilitate the introduction of the concept of relative position introduced by the scheme rather than the concept of absolute position. In actual application, the change of absolute position does not limit the above range.

As shown in FIGS. 1 to 4, the adapter 10 is disposed on the opposite front or rear side of the second housing 11. The second housing 11 is formed with two receiving grooves 111, 112 on its front side and rear side, respectively. The receiving groove 112 is formed on the front side of the second casing 11 and is recessed toward the rear side of the second casing 11; the receiving groove 111 is formed on the rear side of the second casing 11 and is recessed in a direction opposite to the recess of the receiving groove 112. . The adapter interface 18 is disposed in the receiving slot 112 formed on the front side of the second housing 11; the adapter interface 17 is disposed in the receiving slot 111 formed on the rear side of the second housing 11.

As shown in FIG. 4, when the battery pack 30 is coupled to the adapter interface 18, the battery pack 30 is at least partially received in the receiving slot 112; likewise, when the battery pack 20 is coupled to the mating interface 17, it is also at least partially It is housed in the receiving groove 111.

The advantage of this is that when the battery pack is connected to the adapter through the adapter interface, the receiving slot formed on the outer side of the second housing accommodates part of the battery pack, thereby reducing the overall size of the battery pack and the adapter, especially in the battery pack. Big time. Moreover, the inside of the adapter needs to accommodate the circuit board and the electronic components, and they need to dissipate heat during operation, so the internal space of the adapter needs to ensure a certain space. The design of the receiving slot can ensure the volume of the internal space of the adapter while taking into account the battery pack and the adapter. The overall size of the composition. In addition, the portion of the second casing forming the receiving groove can protect the battery pack from the left and right sides so that the battery pack is not subjected to impact and damage first in the event of a fall or impact.

As shown in Figures 1-3, the adapter 10 also includes a handle 19 for the user to hold. The handle 19 is disposed between the two fitting interfaces 17, 18; and the handle 19 is formed substantially in the left-right direction; the two battery packs are provided when the adapter 10 is provided with the weight of the adapter 10, 18 are connected to the battery pack The handle 19 is balanced, and the adapter 10 itself is also balanced relative to the handle 19 after the battery pack is removed.

As a specific solution, in the plane shown in Fig. 2, that is, the plane perpendicular to the vertical direction, the projection of the center of gravity G1 of the adapter 10 falls on the projection of the handle 19 in this plane.

As a specific solution, in the plane shown in FIG. 2, that is, in a plane perpendicular to the vertical direction, the projection of the overall center of gravity G2 of the adapter 10 and all the battery packs connected to the adapter 10 falls on the plane of the handle 19 in the plane. In the projection.

In addition, due to the need of high-power power supply, the overall configuration of the adapter 10 and the battery pack tends to be heavy. Users need to use both hands to carry. As an alternative, the adapter may be provided with more than two handles, which may be disposed at the positions indicated by the two dashed boxes 191 and 192 as shown in FIG. 2, which is known from FIG. And 18 are located between the two handles. If the two handles are far apart, the battery pack is also located between the two handles.

As shown in FIGS. 1 through 4, the adapter 10 further includes support seats 31, 32 for supporting the battery pack 30 when the battery pack 30 is coupled to the adapter interface 18. The support base 32 includes at least one support portion 32a beyond the connection structure 185, and the center of gravity of the battery pack 30 is positioned above the support portion 32a when the battery pack 20 is attached to the adapter interface 18. Further, the center of gravity of the battery pack 30 is located outside the connection structure 185 and above the support portion 32a. The support base 32 is mated with the adapter interface 18 and the support base 31 is mated with the adapter interface 17. A plurality of adapter interfaces are provided with a plurality of support seats to support a plurality of battery packs. At the same time, the plurality of support seats are also matched with the plurality of receiving slots, and each receiving slot is provided with a corresponding support seat. The connection structure is for connecting the first housing and the second housing.

As shown in FIGS. 1 to 5, the second housing 11 is provided with a receiving groove 112 formed at the bottom of the receiving groove 112 and protruding outwardly from the receiving groove 112. The support base 32 is at least partially located below the adapter interface 18 and projects out of the adapter interface 18 in the opposite direction of the recess of the receiving slot 112.

The handle 19 and the support base 32 are respectively disposed on opposite sides of the adapter interface 18.

As shown in FIGS. 1 through 5, the guide rails 185a and 185b are used to slidably connect the battery pack 30 to the adapter 10. Further, the rails 185a and 185b are used to slidably connect the battery pack 30 to the adapter 10 in a direction in which the receiving slot 112 extends.

The adapter 10 is provided with a mid-section. Two or more adapter interfaces are used to connect the battery pack to the adapter symmetrically with respect to the mid-face. In particular, the adaptation interface 17 and the adaptation interface 18 are symmetric about the mid-face. The guide rails 185a and 185b are for slidably connecting the battery pack 30 to the adapter 10 in the direction of the center facet.

As shown in FIGS. 7 to 13, the adapter 40 includes a second housing 41, an inverter, and a rectifier. The second housing 41 enables the battery packs 20, 30 to be detachably coupled to the adapter 40. The second housing 41 houses an inverter or/and a rectifier.

The inverter can convert the direct current output from the battery pack connected to the adapter 40 into alternating current; the rectifier can convert the alternating current that the adapter 40 is connected into the direct current that can charge the battery pack. The inverter and the rectifier are composed of corresponding circuit boards and circuit components, and the circuit board and circuit components constituting the inverter and the rectifier are accommodated. In the accommodating cavity formed by the second housing 41.

The adapter 40 also includes adapter interfaces 47, 48 and a fan 401. The adapter interfaces 47, 48 connect the battery packs 20, 30 to the adapter 40. Fan 401 is used to generate components within the airflow cooling adapter 40. Fan 401 can be driven to rotate about a pivot axis.

At least one of the two or more mating interfaces is disposed on a front side of the second housing. Specifically, the adapter interface 47 is disposed on the rear side of the second housing 41 , and the adapter interface 48 is disposed on the front side of the second housing 41 . At the same time, the second casing 41 forms a vent hole through which the airflow generated by the fan 401 passes, and the fan 401 is disposed inside the second casing 41. Specifically, the fan 401 is disposed in the adapter 40 and located to the left or right of the adapter interfaces 47, 48. In particular, the fan 401 is disposed in the second housing 41 and is located on the left or right side of the adapter interfaces 47, 48.

The adapter 40 includes circuit boards 402a, 402b, 402c, a semiconductor device 403, and a heat sink 404. The semiconductor device 403 is connected to the circuit board 402a, and the heat sink 404 is connected to the semiconductor device 403. The airflow generated by the fan 401 flows through the heat sink 404 to dissipate heat to the semiconductor device 403.

As shown in FIG. 12, the second casing 41 is formed on its left side with an air inlet 405a for the airflow generated by the fan 401 to enter the inside of the second casing 41, and the second casing 41 is formed on the right side thereof for the fan 401 to be produced. The airflow enters the air outlet 405b inside the second casing 41. The air inlet 405a and the air outlet 405b are staggered in the vertical direction.

The pivot axis of the fan 401 is disposed between the two mating interfaces 47, 48 with the heat sink 404 located between the two mating interfaces 47, 48. The pivot axis of the fan 401 is disposed between the two mating interfaces 47, 48 to create a flow of air flowing from left to right.

The front side or the rear side of the inside of the second casing is disposed above the circuit board. Specifically, as shown in FIGS. 12 and 13, the circuit board 402a is disposed on the rear side of the inside of the second casing 41, and the circuit board 402c is disposed on the front side of the inside of the second casing 41. The heat sink 404 is disposed between the circuit board 402a and the circuit board 402c. The adapter 40 also includes an alternating current input interface that enables the adapter 40 to be connected to alternating current in the electrical grid. The AC input interface is disposed on the left or right side of the adapter 40. Specifically, the AC input interface can be constructed as a power plug 42 as shown in FIG. The AC input interface is disposed on the left side of the adapter 40.

The adapter 40 also includes an AC output interface that causes the adapter 40 to output an alternating current. The AC output interface is disposed on the left or right side of the adapter 40. In particular, the AC output interface can be constructed in the form of a power outlet 43, 44 as shown in FIG. Specifically, the AC output interface is located in the adapter The right side of 40. The AC output interface and the AC input interface are located on opposite sides of the adapter 40.

The adapter 40 also includes a direct current output interface for causing the adapter 40 to output direct current. The DC output interface is located on the left or right side of the adapter 40. Specifically, the DC output interface can be configured as a 5V USB interface 45 as shown in FIG. 9, or can be configured as a 12V vehicle power interface 46 as shown in FIG. 9, and can also be configured as other forms of interfaces. . The DC output interface is located on the right side of the adapter 40. The DC output interface and the AC output interface are located on the same side of the adapter 40. The DC output interface and the AC input interface are located on opposite sides of the adapter 40.

As an optional implementation, the adapter further includes an operation interface for the user to operate the adapter. The operator interface can be placed on the left, right or top side of the adapter.

As an optional implementation, the adapter further includes a display interface for displaying information of the portable power system. The display interface can be placed on the left, right or top side of the adapter.

As an alternative embodiment, the adapter further includes a projector. The projector is used to project an image. Information about portable power systems can be displayed.

As an alternative embodiment, the adapter further includes a display. The display is used to display information about the adapter.

As an alternative embodiment, the adapter further includes a player. The player can play video or music.

As an alternative embodiment, the portable power system further includes a photovoltaic panel. Photovoltaic panels are used to convert solar energy into electrical energy to charge or input battery packs to an adapter. As an alternative embodiment, the photovoltaic panel can also be arranged on the adapter. Or the adapter includes a photovoltaic panel.

As an alternative embodiment, the adapter further includes an illumination light. The illuminator can use the power of the access adapter for illumination.

As shown in FIG. 6, the adapter 10 further includes a protective frame 33 that is disposed outside the two opposite sides of the second housing 11. The protective frame 33 serves to protect the second housing 11. Specifically, the protection frame 33 includes a top seat 331, a base 332, and a support post 333. The top seat 331 is disposed at the top of the second housing 11 and the user protects the top of the second housing 11. The base 332 is disposed at the bottom of the second housing 11. It is used to protect the bottom of the second housing 11. The support post 333 connects the base 332 and the top seat 331. The adapter 10 can be provided with a plurality of support columns 333 that connect the base 332 and the top seat 331.

The rails slidably connect the battery pack to the adapter. The support column 333 is substantially parallel to the direction of the guide rail extend. The adapter interface is used to connect the battery pack. The adapter interface is disposed on the front side or the rear side of the second housing, and the battery pack is located between the two support seats 31 when connected to the adapter interface. The fan cools the components inside the adapter 10, and the fan is disposed inside the second housing. The fan is disposed between the two support columns 333.

As an alternative embodiment, the adapter 10 further includes a damping device for damping the impact between the protective frame 33 and the second housing 11. In particular, the damping device comprises a flexible member. The flexible member is disposed between the base 332 and the second housing 11 or between the second housing 11 and the top seat 331.

As an alternative embodiment, the damper device includes an elastic member disposed between the base and the top seat. Further play a buffering role. As a specific embodiment, the elastic member is housed in the support post 333. An elastic member is disposed in each of the plurality of support columns 333.

The top seat 331 is provided with or connected with a handle 19 for the user to hold, and the two fitting interfaces 17, 18 are respectively located on both sides of the handle.

The use of portable power system 100 in combination with DC power tool 50 constitutes a new power system. As shown in FIG. 14, the battery packs 20, 30 can be detachably connected to the DC power tool 50 for powering them. The DC power tool includes a power device. The electric device can include a motor.

The portable power system 100 is combined with a DC power tool 50 and an AC power tool 60 to form a new power system. As shown in FIG. 14, the battery packs 20, 30 can be detachably connected to the DC power tool 50 for powering them. The AC power tool 60 includes a motor that outputs AC power to the AC power tool 60 to power the AC power tool 60.

As shown in Figure 17, an electrical energy system includes two adapters, a first adapter and a second adapter. Both adapters can use the same adapter or different adapters. As a specific embodiment. Both the first adapter and the second adapter employ an adapter 10. The battery pack is coupled to the adapter 10. The two adapters 10 collectively power the power tool 70. Such an electrical energy system can also include multiple adapters. Not limited to two.

As an alternative embodiment, the two adapters 10 are simultaneously connected to the power tool 70. The voltages that the adapter 10 supplies to the power tool 70 can be superimposed. For example, both adapters 10 output 36V, and can be superimposed to 72V to power the power tool 70. Or two adapters 10 have an output of 36V and the other output of 48V is superimposed to 84V. Of course, it is also possible to adopt a method of not superimposing, and both adapters 10 output 36V, and still output 36V for the power tool 70. Of course, the two adapters 10 can also select the output to simultaneously output the alternating current to the power tool 70, or simultaneously output the direct current or one output alternating current and the other is the power tool. 70 output DC power.

As another alternative embodiment, the two adapters 10 are connected in series and then connected to the power tool 70. It can be understood that one adapter 10 charges another adapter 10, and then the charged adapter 10 supplies power to the power tool 70. Or the first adapter 10 supplies power to the power tool 70, and the second adapter 10 is connected to the first adapter 10 and does not charge the first adapter 10. The first adapter 10 only serves as a transmission function of, for example, a cable, thereby being the power tool 70. powered by.

The basic principles, main features and advantages of the present invention have been shown and described above. It should be understood by those skilled in the art that the above embodiments are not intended to limit the invention in any way, and the technical solutions obtained by means of equivalent substitution or equivalent transformation are all within the scope of the invention.

Claims (48)

1. A portable electrical energy system comprising:

   At least one battery pack that can power the power tool;

   An adapter for causing the battery pack to output electrical energy or input electrical energy to the battery pack;

   among them,

   The battery pack includes:

   a battery cell for storing electrical energy;

   a first housing for accommodating the battery core;

   The adapter includes:

   An inverter that converts the direct current outputted by the battery pack into an alternating current;

   a rectifier that converts alternating current into direct current capable of charging the battery pack;

   a second housing for housing the inverter or/and the rectifier;

   The battery pack is detachably connected to the adapter.
2. The portable electrical energy system of claim 1 wherein:

   The adapter further includes:

   An AC input interface for connecting the adapter to an alternating current;

   An AC output interface for causing the adapter to output an alternating current;

   Wherein the alternating current input interface is connected to the rectifier; the alternating current output interface is connected to the inverter.
3. The portable power system of claim 2 wherein:

   The output voltage of the alternating current output interface is equal to the access voltage of the alternating current input interface.
4. The portable electrical energy system of claim 1 wherein:

   The adapter further includes:

   a direct current output interface for causing the adapter to output direct current;

   The output voltage of the DC output interface is lower than the rated voltage of the battery pack.
5. The portable electrical energy system of claim 1 wherein:

   The adapter further includes:

   a plurality of direct current output interfaces for causing the adapter to output a direct current lower than a rated voltage of the battery pack;

   One of the DC output interfaces has a lower voltage than the other of the DC output interfaces Pressure.
6. The portable electrical energy system of claim 1 wherein:

   The adapter further includes:

   a direct current input interface for causing the adapter to access a direct current that charges the battery pack.
7. The portable electrical energy system of claim 1 wherein:

   The portable power system has a plurality of the battery packs, one of which is capable of charging another of the battery packs through the adapter.
8. The portable electrical energy system of claim 1 wherein:

   The portable power system has a plurality of battery packs having different rated voltages, wherein one of the battery packs can charge another of the battery packs through the adapter.
9. The portable electrical energy system of claim 1 wherein:

   The rated voltage of the battery pack is greater than or equal to 30V and less than or equal to 350V.
10. The portable electrical energy system of claim 1 wherein:

    The weight of the battery pack is greater than or equal to 1 kg and less than or equal to 10 kg.
11. The portable electrical energy system of claim 1 wherein:

    The power capacity of the battery pack is greater than or equal to 100 Wh and less than or equal to 2000 Wh.
12. The portable electrical energy system of claim 1 wherein:

    The ratio of the total amount of all the battery packs that the adapter can be combined to the total weight of the portable electrical energy system ranges from 7 Wh/kg to 200 Wh/kg.
13. The portable electrical energy system of claim 1 wherein:

    The ratio of the total mass of all of the battery packs to which the adapter can be combined to the total weight of the portable electrical energy system ranges from 0.15 to 0.90.
14. The portable electrical energy system of claim 1 wherein:

    The ratio of the voltage of the battery pack to the voltage of the alternating current output by the adapter ranges from 0.07 to 1.5.
15. The portable electrical energy system of claim 1 wherein:

    The ratio of the voltage of the battery pack to the voltage of the direct current output by the adapter is defined as a straight-to-voltage ratio; the straight-varying voltage ratio ranges from 0.5 to 32.
16. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for detachably connecting the battery pack to the adapter;

    The adaptation interface includes:

    An electrical connection terminal for electrically connecting with the battery core of the battery pack;

    a connecting structure for connecting the first housing and the second housing;

    The electrical connection terminal is connected to the inverter and the rectifier.
17. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Two or more adapter interfaces for connecting the battery pack to the adapter;

    Two of the adapter interfaces are disposed on opposite sides of the second housing.
18. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    The second housing is provided with:

    a receiving groove formed on one side of the second housing and recessed toward the opposite other side;

    The adapter interface is disposed in the receiving slot to at least partially receive the battery pack in the receiving slot.
19. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    a handle for the user to hold;

    Two or more adapter interfaces for connecting the battery pack to the adapter;

    Two of the adapter interfaces are disposed on opposite sides of the second housing such that the battery pack is balanced relative to the handle when coupled to the mating interface on the two sides.
20. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Two handles for the user to hold;

    Adapting an interface for connecting the battery pack to the adapter;

    Two of the handles are disposed on both sides of the adapter interface such that the battery pack is located between the two handles when connected to the adapter interface.
21. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    a support base for supporting the battery pack when the battery pack is connected to the adapter interface;

    The adaptation interface includes:

    An electrical connection terminal for electrically connecting with the battery core of the battery pack;

    a connecting structure for connecting the first housing and the second housing;

    The support base includes at least one support portion beyond the connection structure such that the center of gravity of the battery pack is outside the connection structure and located at the support portion when the battery pack is connected to the adapter interface Above.
22. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    a support base for supporting the battery pack when the battery pack is connected to the adapter interface;

    The adaptation interface includes:

    An electrical connection terminal for electrically connecting with the battery core of the battery pack;

    a connecting structure for connecting the first housing and the second housing;

    The support base includes at least one support portion beyond the connection structure such that a center of gravity of the battery pack is above the support portion when the battery pack is connected to the adapter interface.
23. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    a support base for supporting the battery pack when the battery pack is connected to the adapter interface;

    The second housing is provided with:

    a receiving groove formed on one side of the second housing and recessed toward the opposite other side;

    The support seat is formed at a bottom of the receiving groove and protrudes outward from the receiving groove.
24. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    a support base for supporting the battery pack when the battery pack is connected to the adapter interface;

    The second housing is provided with:

    a receiving groove formed on one side of the second housing and recessed toward the opposite other side;

    The adapter interface is disposed in the receiving slot to at least partially receive the battery pack in the receiving slot;

    The support seat is at least partially located below the adapter interface and protrudes from the adapter interface in an opposite direction of the recess of the receiving slot.
25. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    a handle for the user to hold;

    Adapting an interface for connecting the battery pack to the adapter;

    a support base for supporting the battery pack when the battery pack is connected to the adapter interface;

    The handle and the support base are respectively disposed on opposite sides of the adapter interface.
26. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    The second housing is provided with:

    a receiving groove formed on one side of the second housing and recessed toward the opposite other side;

    The adaptation interface includes:

    a connecting structure for connecting the first housing and the second housing;

    The connection structure includes:

    a rail for slidably connecting the battery pack to the adapter in a direction in which the receiving slot extends.
27. The portable electrical energy system of claim 1 wherein:

    The adapter is provided with a mid-section and further comprising:

    Two or more adapter interfaces for connecting the battery pack to the adapter symmetrically with respect to the middle facet;

    The adaptation interface includes:

    a connecting structure for connecting the first housing and the second housing;

    The connection structure includes:

    a guide rail for slidably connecting the battery pack to the adapter in a direction parallel to the center facet.
28. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a fan for cooling components inside the adapter;

    Adapting an interface for connecting the battery pack to the adapter;

    The adapter interface is disposed on a front side of the second housing; the second housing forms a ventilation hole through which airflow generated by the fan passes at least on a left or right side thereof; the fan is disposed at the The inside of the second housing.
29. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a fan for cooling components inside the adapter;

    Adapting an interface for connecting the battery pack to the adapter;

    The adapter interface is disposed on a front side of the second housing; the fan is disposed in the adapter and located on a left side or a right side of the adapter interface.
30. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a fan for cooling components inside the adapter;

    Adapting an interface for connecting the battery pack to the adapter;

    The adapter interface is disposed on a front side or a rear side of the second housing; the second housing forms an air inlet for the airflow generated by the fan to flow into the interior of the second housing at least on a left side thereof a hole; the second casing forms an air outlet hole for the airflow generated by the fan to flow into the interior of the second casing at least on a right side thereof.
31. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a fan for cooling components inside the adapter;

    Adapting an interface for connecting the battery pack to the adapter;

    The adapter interface is disposed on a front side or a rear side of the second housing; the second housing forms an air inlet for the airflow generated by the fan to flow into the interior of the second housing at least on a left side thereof a hole; the second casing forms an air outlet hole for the airflow generated by the fan to flow into the interior of the second casing at least on a right side thereof; The tuyere and the air outlet are staggered in the up and down direction.
32. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a fan that can be driven to rotate about a pivot axis;

    a circuit board disposed inside the second housing;

    a semiconductor device connected to the circuit board;

    a heat sink connected to the semiconductor device;

    The circuit board is substantially parallel to a pivot axis of the fan; the heat sink and the pivot axis of the fan are located on the same side of the circuit board.
33. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a fan that can be driven to rotate about a pivot axis;

    Two or more adapter interfaces for connecting the battery pack to the adapter;

    a circuit board disposed inside the second housing;

    a semiconductor device connected to the circuit board;

    a heat sink connected to the semiconductor device;

    The pivot axis of the fan is disposed between two of the mating interfaces; the heat sink is located between the two mating interfaces.
34. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    Two or more adapter interfaces for connecting the battery pack to the adapter;

    a fan that can be driven to rotate about a pivot axis;

    a circuit board disposed inside the second housing;

    a semiconductor device connected to the circuit board;

    a heat sink connected to the semiconductor device;

    The adapter interface is disposed on a front side or a rear side of the second housing; a pivot axis of the fan is disposed between the two adapter interfaces and can generate airflow flowing from left to right.
35. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    Two or more adapter interfaces for connecting the battery pack to the adapter;

    a fan that can be driven to rotate about a pivot axis;

    a plurality of circuit boards disposed inside the second housing;

    a semiconductor device connected to the circuit board;

    a heat sink connected to the semiconductor device;

    The adapter interface is disposed on a front side or a rear side of the outer portion of the second housing; at least one of the plurality of circuit boards is disposed on a front side or a rear side of the interior of the second housing, the heat sink Located between two of the boards.
36. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    Adapting an interface for connecting the battery pack to the adapter;

    An AC input interface for connecting the adapter to an alternating current;

    The adapter interface is disposed on a front side or a rear side of the adapter; the AC input interface is disposed on a left side or a right side of the adapter.
37. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    Adapting an interface for connecting the battery pack to the adapter;

    An AC output interface for causing the adapter to output an alternating current;

    The adapter interface is disposed on a front side or a rear side of the adapter; the AC output interface is disposed on a left side or a right side of the adapter.
38. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    Adapting an interface for connecting the battery pack to the adapter;

    a direct current output interface for causing the adapter to output direct current;

    The adapter interface is disposed on a front side or a rear side of the adapter; the DC output interface is disposed on a left side or a right side of the adapter.
39. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    A protective frame is disposed outside the two opposite sides of the second housing.
40. A portable electrical energy system according to claim 39, wherein:

    The protection framework also includes:

    a base disposed at a bottom of the second housing;

    a top seat disposed at a top of the second housing;

    Support columns are respectively connected to the base and the top seat.
41. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a protection frame for protecting the second housing;

    Adapting an interface for connecting the battery pack to the adapter;

    The protection framework also includes:

    a base for protecting a bottom of the second housing;

    a top seat for protecting a top of the second housing;

    Supporting columns connected to the base and the top seat, respectively;

    The adapter interface is disposed on a front side or a rear side of the second housing to position the battery pack between the two support posts when the battery pack is coupled to the adapter interface.
42. The portable electrical energy system of claim 1 wherein:

    The adapter further includes:

    a protection frame for protecting the second housing;

    Adapting an interface for connecting the battery pack to the adapter;

    The protection framework also includes:

    a base for protecting a bottom of the second housing;

    a top seat for protecting a top of the second housing;

    Supporting columns connected to the base and the top seat, respectively;

    The top seat is provided with or connected with a handle for the user to hold; the adapter interfaces are respectively located at two sides of the handle.
43. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    a protection frame for protecting the second housing;

    The adaptation interface includes:

    a guide rail for slidably connecting the battery pack to the adapter;

    The protection framework also includes:

    The support columns are formed generally in a direction parallel to the guide rails.
44. The portable electrical energy system of claim 1 wherein:

    The adapter includes:

    Adapting an interface for connecting the battery pack to the adapter;

    Protecting the frame, providing an outer side of the second casing;

    a fan disposed inside the second housing;

    The protection framework includes:

    a plurality of support columns disposed at a position between the battery packs connected to the adapter interface;

    The fan is disposed between the two support columns.
45. An adapter that includes:

    An inverter for converting a direct current of the output of the battery pack into an alternating current;

    a rectifier for causing alternating current to become direct current charged by the battery pack;

    a housing for housing the inverter or/and the rectifier;

    An AC input interface for connecting the adapter to an alternating current;

    An AC output interface for causing the adapter to output an alternating current;

    Adapter interface for detachably connecting a battery pack that can power a power tool;

    Wherein the alternating current input interface is connected to the rectifier; the alternating current output interface is connected to the inverter.
46. An electrical energy system comprising:

    DC power tool, including a power device;

    a battery pack detachably connected to and powered by the DC power tool;

    An adapter for causing the battery pack to output electrical energy or input electrical energy to the battery pack;

    among them,

    The battery pack includes:

    a battery cell for storing electrical energy;

    a first housing for accommodating the battery core;

    The adapter includes:

    An inverter for converting a direct current of the output of the battery pack into an alternating current;

    a rectifier for causing alternating current to become direct current charged by the battery pack;

    a second housing for housing the inverter or/and the rectifier;

    The battery pack is detachably connected to the adapter.
47. An electrical energy system comprising:

    DC power tool, including a power device;

    AC power tool, including a motor;

    a battery pack detachably connected to and powered by the DC power tool;

    An adapter for causing the battery pack to output electrical energy or input electrical energy to the battery pack;

    among them,

    The battery pack includes:

    a battery cell for storing electrical energy;

    a first housing for accommodating the battery core;

    The adapter includes:

    An inverter for converting a direct current of the output of the battery pack into an alternating current;

    a rectifier for causing alternating current to become direct current charged by the battery pack;

    a second housing for housing the inverter or/and the rectifier;

    An AC output interface for outputting AC power to the AC power tool;

    The battery pack is detachably connected to the adapter; the alternating current output interface is connected to the inverter.
48. An electrical energy system comprising:

    Battery pack

    Power tool, including a motor;

    a first adapter for causing the battery pack to output electrical energy or input electrical energy to the battery pack;

    a second adapter for causing the battery pack to output electrical energy or input electrical energy to the battery pack;

    The battery pack includes:

    a battery cell for storing electrical energy;

    a first housing for accommodating the battery core;

    The first adapter includes:

    a first inverter for converting a direct current of the output of the battery pack into an alternating current;

    a first rectifier for causing alternating current to become direct current charged by the battery pack;

    The second adapter includes:

    a second inverter for converting a direct current of the output of the battery pack into an alternating current;

    a second rectifier for causing alternating current to become direct current charged by the battery pack;

    The battery pack is detachably coupled to the first adapter and/or the second adapter;

    The first adapter and the second adapter can collectively power the power tool.

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