TWM543501U - Conductive mechanism and related voltage dynamic auto-balancing power storage device - Google Patents

Abstract

A voltage dynamic auto-balancing power storage device includes a casing, an input terminal set, an output terminal set, a protection circuit board, and a conductive component. At least one power storage unit is disposed inside the casing. The input terminal set is disposed on a side of the casing, and the output terminal set is disposed on the other side of the casing to connect with the input terminal set of another voltage dynamic auto-balancing power storage device. The protection circuit board is electrically connected to the power storage unit. Two ends of the conductive component are respectively connected with the input terminal set and the output terminal set, and the input terminal set and the output terminal set are connected with the power storage unit via the conductive component and the protection circuit board.

Description

Conduction mechanism and voltage dynamic self-balancing energy storage device thereof

The present invention provides a conduction mechanism and an energy storage device capable of arbitrarily performing series/parallel connection, and particularly a new design conduction mechanism for charging and discharging in a physical dynamic self-balancing manner, plus a Y-shaped surface contact terminal or a conduction. The new mechanism of the module is designed to improve the expansion of its voltage and capacity, and to dynamically self-balance between the energy storage devices at any time (when not charging, charging, discharging, and charging) A conductive mechanism that increases the useful life and expands the use of the device and its voltage dynamic self-balancing energy storage device.

Please refer to FIG. 1. FIG. 1 is a schematic diagram of a conventional rechargeable battery 10 of the prior art. The rechargeable battery 10 is provided with an input end 14 and an output end 16 respectively at two ends of the housing 12, and the input end 14 and the output end 16 are electrically connected to the storage element 18, respectively. When the two rechargeable batteries 10 are connected in series or in parallel to form a battery combination and are charged by an external power device, the external power signal is first charged to the lowest-voltage or worst-quality rechargeable battery 10 according to physical characteristics; The charging of the rechargeable battery 10 deteriorates the quality of the rechargeable battery 10, causing the user's service life to be greatly reduced and easily damaged. Then, the external power signal is charged to another rechargeable battery 10 having the second lowest voltage or the second worst quality depending on the physical characteristics. The quality of the other rechargeable battery 10 is continuously deteriorated, and the overall performance of the battery assembly is eventually destroyed. When discharging, the same defect is still caused by the same principle of charge and discharge. A conventional improvement method is additionally provided with a set of electronic central control circuits in the battery assembly to sense and control the input and/or output voltage and current of each rechargeable battery 10, but The circuit of the sub-control circuit is complicated and expensive. The combination of series and parallel connection makes the line more complicated, and the fault is easy to be out of control. Once the electronic central control circuit fails, the performance and life of the battery combination will be rapidly degraded and prone to danger. .

The present invention provides a through current guiding channel for connecting the input terminal group and the output terminal group of the conduction mechanism in the voltage dynamic self-balancing energy storage device, and the expansion and the expansion of the voltage and capacity by the design of the conduction mechanism The voltage dynamic self-balancing energy storage between the energy storage devices at any time (when not charging, charging, discharging, charging and discharging) dynamic self-balancing to enable multiple voltage dynamic self-balancing energy storage combined in series or parallel mode The voltage and power between the devices are consistent (such as the use of a single battery), so that the voltage dynamic self-balancing energy storage device can greatly improve the reliable service life, and can be expanded to be used in any DC energy storage occasion to solve the above problems. . The conduction mechanism enables the voltage dynamic self-balancing energy storage device to dynamically self-balance according to the principle of electrical physical pressure. The voltage and current are freely flowable on the conduction mechanism according to the electrical physical voltage and current from high to low. The characteristic) dynamic flow at any time until all voltage dynamic self-balancing energy storage devices reach the voltage balance.

The patent application scope of the present invention discloses a voltage dynamic self-balancing energy storage device, which comprises a casing, a first clamping male terminal of an input terminal group, a second clamping female terminal of an output terminal group, and a conduction mechanism. . The interior of the housing houses at least one energy storage unit. The first clamping male terminal of the input terminal group is disposed on one side of the housing, and the second clamping female terminal of the output terminal group is disposed on the other side of the housing. The output terminal group is used to connect an input terminal group of another voltage dynamic self-balancing energy storage device. Both ends of the conduction member are coupled to the input terminal group and the output terminal group, respectively. The conduction mechanism is electrically connected to the energy storage unit via a protection circuit board. The conducting mechanism is controlled by the protection circuit board voltage and is different according to the parameter value of the power signal of the energy storage device and the other voltage dynamic self-balancing energy storage device According to the physical specific pressure principle, the current controlled by the conduction mechanism and the voltage controlled by the protection circuit board enters or leaves the power signal of the energy storage unit until the voltage power is dynamically balanced with other voltage dynamic self-balancing energy storage devices.

The scope of the patent application of the present invention further discloses that the specification of the impedance of the energy storage unit is the same as that of the energy storage unit of one of the other voltage dynamic self-balancing energy storage devices. The voltage dynamic self-balancing energy storage device further includes a first clamping male terminal and a second clamping female terminal respectively disposed at opposite ends of the conducting mechanism for inserting the other voltage dynamic self-balancing energy storage device. Corresponding to the clamping terminal. The second clamping female terminal includes a bottom portion, a clamping portion and a slope guiding portion. One end of the clamping portion is coupled to the bottom portion for embossing the corresponding first clamping male terminal of the other voltage dynamic self-balancing energy storage device in a surface contact manner (eg, a plate shape, a circular shape, or the like). The inclined guiding portion is connected to the other opposite end (ie, the top end) of the clamping portion for guiding the corresponding first clamping male terminal of the other voltage dynamic self-balancing energy storage device to contact the clamping portion.

The patent application scope of the present invention further discloses a conduction mechanism applied to a voltage dynamic self-balanced energy storage device for serial-parallel connection with another voltage dynamic self-balancing energy storage device, and the voltage dynamic self-balanced energy storage device The housing has a first clamping male terminal of an input terminal set and a second clamping female terminal of an output terminal set. The conducting mechanism includes a conducting member coupled to a first clamping male terminal and a second clamping female terminal to form a conduction mechanism for the input and output DC channels. The two ends of the conduction mechanism respectively connect the first clamping male terminal of the input terminal group and the second clamping female terminal of the output terminal group. The first clamping male terminal of the input terminal group and the second clamping female terminal of the output terminal group are electrically connected to the protection board through the first transmission line through the conduction member, and the voltage control thereof is electrically connected by the second transmission line The energy storage unit of the voltage dynamic self-balancing energy storage device has both charging and discharging states. The conducting mechanism detects the electricity of the energy storage device and the other voltage dynamic self-balancing energy storage device according to the protection plate The difference in the parameter value of the force signal is based on the high voltage current and the natural low voltage and high speed flow characteristics to dynamically self-balance the power signal into or out of the energy storage device. The first clamping male terminal is disposed at one end of the conduction member. The second clamping female terminal is disposed at the other opposite end of the conducting member for being inserted into a corresponding first clamping male terminal of the other voltage dynamic self-balancing energy storage device.

This creation does not need to set up expensive electronic central control circuit, but uses the physical dynamic self-balancing characteristic induced by the conduction mechanism, so that the voltage and power of multiple voltage dynamic self-balancing energy storage devices connected together can be naturally The dynamic self-balancing physical characteristics of the low-voltage and high-speed flow characteristics make the voltage of all the voltage dynamic self-balancing energy storage devices connected together become uniform in a short time; even if another voltage dynamic self-balancing energy storage is connected The voltage-dynamic self-balancing energy storage device can still automatically initiate a dynamic self-balancing current flow due to the through-current guiding channel of the conducting mechanism, so that all the series and/or parallel combined energy storage of the new energy storage combination The device quickly reaches the voltage balance state as if it were combined into a single large battery.

10‧‧‧Rechargeable battery

12‧‧‧ housing

14‧‧‧ input

16‧‧‧ Output

18‧‧‧Power storage components

20‧‧‧Voltage dynamic self-balancing energy storage device

22‧‧‧ housing

24‧‧‧Input terminal set using the first clamping male terminal

241‧‧‧ input positive terminal

242‧‧‧ input negative terminal

26‧‧‧Using the output terminal set of the second clamping female terminal

261‧‧‧ output positive terminal

262‧‧‧ output negative end

28‧‧‧Protected circuit board

30‧‧‧Connected institutions

31‧‧‧Connecting components

32‧‧‧ Energy storage unit

34‧‧‧First transmission line

36‧‧‧Second transmission line

38, 38', 38" ‧ ‧ first clamping male terminal

40, 40', 40" ‧ ‧ second clamping female terminal

42‧‧‧ bottom

44‧‧‧Clamping Department

46‧‧‧ oblique guide

48‧‧‧First card fittings

50‧‧‧Second card fittings

52‧‧‧DC one-way charging port

54‧‧‧Active link cable

56, 56', 56" ‧ ‧ conduction module

58‧‧‧ third transmission line

Figure 1 is a schematic illustration of a conventional rechargeable battery of the prior art.

FIG. 2 is a schematic diagram showing the appearance of a voltage dynamic self-balancing energy storage device according to an embodiment of the present invention.

FIG. 3 is a schematic diagram of a combination of a plurality of voltage dynamic self-balancing energy storage devices according to an embodiment of the present invention.

FIG. 4 is a schematic diagram showing the internal structure of the voltage dynamic self-balancing energy storage device of the present embodiment in parallel.

FIG. 5 is a schematic diagram of the first embodiment of the present invention, which has a first clamping male terminal, a second clamping female terminal, and a conducting mechanism and a conducting module.

FIG. 6 is a schematic diagram of a plurality of voltage dynamic self-balancing energy storage devices connected in series by a movable connecting cable according to an embodiment of the present invention.

7 and 8 are schematic views of the conduction modules having male and female terminals of different shapes according to other embodiments of the present invention.

Please refer to FIG. 2 to FIG. 4 , FIG. 2 is a schematic diagram of the appearance of the voltage dynamic self-balancing energy storage device 20 according to the embodiment of the present invention, and FIG. 3 is a plurality of voltage dynamic self-balancing energy storage devices 20 according to the present embodiment. FIG. 4 is a schematic diagram showing the internal structure of the voltage dynamic self-balancing energy storage device 20 in parallel according to the present embodiment. The voltage dynamic self-balancing energy storage device 20 includes a housing 22, an input terminal set 24 having a first clamping male terminal 38, an output terminal set 26 having a second clamping female terminal 40, a protective circuit board 28, and a conduction mechanism 30. The voltage dynamic self-balancing energy storage device 20 can be a battery case. The housing 22 can be any type of receiving member, not limited to a rigid container or a flexible packaging material; the housing 22 may even be directly removed, and only the conduction mechanism 30 is disposed between the input terminal group 24 and the output terminal group 26 and connected The circuit board 28 and the energy storage unit 32 are protected. The housing 22 houses at least one energy storage unit 32, that is, the voltage dynamic self-balancing energy storage device 20 may be a single core (one energy storage unit 32) battery, or may be connected in series/parallel to a plurality of batteries (multiple The battery pack of the energy storage unit 32). The first clamping male terminal 38 of the input terminal set 24 and the second clamping female terminal 40 of the combined output terminal set 26 are generally disposed on opposite sides of the housing 22, and the housing engaging mechanism is used to force the positioning of the LEGO. The building block combination mode is used to connect the second clamping female terminal 40 of the corresponding output terminal group 26 of the adjacent voltage dynamic self-balancing energy storage device 20 and the first clamping male terminal 38 of the corresponding input terminal group 24. Of course, the present invention can also provide the second clamping female terminal 40 in the input terminal group 24 and the first clamping male terminal 38 in the output terminal group 26. The application aspect is not limited thereto. The protection circuit board 28 is disposed within the housing 22. One end of the protection circuit board 28 is electrically connected to the conduction mechanism 30 via the first transmission line 34, and the other end of the protection circuit board 28 is electrically connected to the energy storage unit 32 by the second transmission line 36. Both ends of the conduction mechanism 30 are connected to the input terminal group 24 having the first clamping male terminal 38 and the output terminal group 26 having the second clamping female terminal 40, respectively. The first clamping male terminal 38 of the input terminal group 24 and the output terminal group 26 The two clamping female terminals 40 are connected to the protection circuit board 28 via the conduction mechanism 30 by the first transmission line 34, and are electrically connected to the energy storage unit 32 via the voltage control function of the protection circuit board 28. The input terminal group 24 internally houses the first clamping male terminal 38 and has a concave structure relative to the housing 22 to prevent the user from accidentally touching the first clamping male terminal 38 and receiving electric shock, and can also be used for accommodating another voltage. The output terminal group of the dynamic self-balancing energy storage device is combined with the second clamping female terminal built in the output terminal group, so that adjacent voltage dynamic self-balancing energy storage devices can be combined in parallel. The output terminal group 26 protrudes from the housing 22 for receiving the second clamping female terminal 40.

The combination of the first clamping male terminal 38 of the input terminal set 24 can be divided into a plurality of input positive terminal 241 and input negative terminal 242, and the combination of the second clamping female terminal 40 of the output terminal group 26 can be divided into a plurality of output positive terminals 261. And the output negative terminal 262. The conduction mechanism 30 is bridged between the input terminal group 24 and the output terminal group 26, and the number is not limited to the figure; for example, the voltage dynamic self-balancing energy storage device 20 may have six or eight conduction mechanisms 30 or more for The split reduces the temperature rise. The number of combinations of the first clamping male terminal 38 of the input terminal block 24 and the positive/negative terminal of the second clamping female terminal 40 of the output terminal group 26 also varies with the number of the conducting mechanisms 30. When charging or discharging the voltage dynamic self-balancing energy storage device 20, the first clamping male terminal 38 of the input terminal group 24 first receives the power signal from the external power device, and then the power signal is preferably directly via the conduction mechanism 30. And simultaneously transmitted to the second clamping female terminal 40 of the output terminal group 26 and/or the voltage control via the protective circuit board 28 is electrically connected to the energy storage unit 32, rather than only to the energy storage unit 32. In this way, when a plurality of voltage dynamic self-balancing energy storage devices 20 are combined, for example, a plurality of voltage dynamic self-balancing energy storage devices 20 are connected in series or in parallel, and a voltage dynamic self-balancing energy storage device 20 is charged from an external power device. The power signal is not only preferentially charged into the voltage dynamic self-balancing energy storage device 20 having the lowest voltage among the plurality of voltage dynamic self-balancing energy storage devices 20, but the through current guiding channel established by the conduction mechanism 30 is allowed to have a high voltage. The current in the voltage dynamic self-balancing energy storage device 20 is actively turned to a voltage with a low voltage via the conduction mechanism 30. The dynamic self-balancing energy storage device 20 autonomously flows at a high speed; that is, the high voltage of the conduction mechanism 30 simultaneously flows to all of the voltage dynamic self-balancing energy storage devices 20 that are lower than the voltage of the conduction mechanism 30, respectively. The voltage difference between the different voltage dynamic self-balancing energy storage devices 20 can also be utilized, and the dynamic self-balancing current flow is initiated by the conduction mechanism 30 by the voltage self-balancing platform; when discharging, vice versa. At this time, the protection circuit board 28 in the energy storage device 20 is designed to have a function of charging cutoff and discharge current limit minimum cutoff, and protects the energy storage device 20 by controlling the voltage and current. If the protection circuit board 28 detects that the voltage of the energy storage unit 32 is lower than the voltage of the conduction mechanism 30, the energy storage unit 32 is limited to be charged within 0.5C, and is charged to the set saturation cut-off point. When discharging, if the protection circuit board 28 detects that the voltage of the energy storage unit 32 is higher than the voltage of the conduction mechanism 30, the current is limited to flow in the 2C to discharge the higher voltage current of the energy storage unit 32 into the conduction mechanism 30 via the discharge. Discharge until the set discharge cutoff point. The relevant parameter settings are not limited to this, depending on actual needs. The symbol C is a general term for the battery (the energy storage unit 32), and indicates the amount of current used by the battery to charge and discharge to the cut-off point within one hour. That is, the amount of current used to charge the battery capacity to the cut-off point in one hour during charging; the amount of current used to discharge the battery capacity to the cut-off point in one hour during discharge is generally called 1C.

The voltage dynamic self-balancing energy storage device 20 of the present invention utilizes the physical properties of the conduction mechanism 30 to use a highly conductive material for guiding the flow of voltage and current to achieve a dynamic self-balancing function of the voltage and power. For example, the conduction mechanism 30 may be silver plated. The metal material, but the practical application is not limited to this. In other words, since the conduction member 31 is provided between the first clamp male terminal 38 of the input terminal group 24 and the second clamp female terminal 40 of the output terminal group 26, the conduction member 31 is used to guide the current directly to the input terminal group. A current guiding channel is established between the first clamping male terminal 38 of the output clamp terminal 24 and the second clamping female terminal 40 of the output terminal group 26, and the voltage and current are automatically self-balanced by the physical characteristics of the voltage and the automatic voltage and current flow, and the plurality of connected phases are balanced. The energy storage device 20 does not only charge or discharge from the lowest voltage or worst quality energy storage device. When a plurality of voltage dynamic self-balancing energy storage devices 20 are coupled to form an energy storage combination, the voltages are dynamically self-balancing The energy storage device 20 respectively receives or overflows the adapted power signal according to the difference between the total voltage of the individual voltage and the energy storage combination and the total voltage of the conduction mechanism 30, that is, the conduction mechanism of each voltage dynamic self-balancing energy storage device 20. 30 will dynamically self-balance the power signal of the energy storage device according to other voltages (for example, its voltage and current values), dynamically self-balance the power signal with corresponding parameters to other energy storage devices 20, and let each of the energy storage combinations The current and voltage between the voltage dynamic self-balancing energy storage devices 20 can dynamically flow according to the physical characteristics depending on the conduction mechanism 30 until the voltage balance between all the energy storage devices 20 is consistent within a certain range to reach a stable state. This revolution The improved design makes the energy storage device 20 have the advantage of greatly improving the reliability of the service life; at the same time, the energy storage device 20 can be expanded to be used in any DC energy storage occasion because the voltage can be easily increased or the power can be expanded.

Moreover, the through current guiding channel between the first clamping male terminal 38 of the input terminal group 24 and the second clamping female terminal 40 of the output terminal group 26 can be made in the energy storage combination in a short time. The voltage and current of all voltage dynamic self-balancing energy storage devices 20 generate physical dynamic self-balancing flow, in addition to effectively achieving voltage balance and stability of multiple voltage dynamic self-balancing energy storage devices 20, and further avoiding voltage dynamic self-balanced storage. The components of the energy unit 20 are overheated, so that no additional water-cooled or air-cooled cooling systems are required. However, the conductive mechanism 30 should preferably be made of a material having high heat resistance, high electrical conductivity, and high power characteristics to improve the safety of the energy storage combination; for example, when the energy storage combination is composed of more voltage dynamic self-balancing energy storage devices 20 When the series or parallel connection is combined, the conduction mechanism 30 of each voltage dynamic self-balancing energy storage device 20 needs to have the characteristics of high heat resistance, high conductivity and high power, and is sufficient to safely carry a large current. The number, length, width and thickness of the conduction mechanism 30 are based on the preset power of the electrical energy demand, the built-in quantity of the energy storage unit 32 of each voltage dynamic self-balancing energy storage device 20, and the voltage dynamic self-balanced storage of the energy storage combination. The number of energy devices 20 and the maximum current that the protection circuit board 28 sets to control charging and/or discharging are defined; for safety reasons, the specification of the discharge port is generally not more than 200 amps, but may not be limited thereto.

The voltage dynamic self-balancing energy storage device 20 of the present invention has a specific storage capacity according to the number and specifications of its energy storage unit 32, and is used for supplying power to any type of power device; if the power device requires a large power source, the combination A plurality of voltages dynamically self-balance the energy storage device 20 to form a higher energy storage energy storage combination. Therefore, each of the voltage dynamic self-balancing energy storage devices 20 can accommodate a plurality of energy storage units 32, but the internal impedance coefficients of any of the energy storage units 32 of the energy storage units 32 preferably need to be within a specific range; The plurality of energy storage units 32 in the same voltage dynamic self-balancing energy storage device 20 preferably have the same impedance and the like in the range, and the impedance specifications of the energy storage unit 32 in the different voltage dynamic self-balancing energy storage device 20 They should also be substantially identical within a specific range to ensure the safety and stability of the energy storage combination during charging and discharging.

In particular, the voltage dynamic self-balancing energy storage device 20 can further include a first transmission line 34 connecting the conduction mechanism 30 and the protection circuit board 28, and a second transmission line 36 connecting the protection circuit board 28 and the energy storage unit 32. . The first transmission line 34 and the second transmission line 36 are independent of each other. If the voltage dynamic self-balancing energy storage device 20 is a lithium battery model, the maximum charging current limit that the protection circuit board 28 must start does not exceed 0.5 C until the set saturation point is cut off. The discharge is limited to 2C, and is discharged to the set discharge cutoff point. The relevant parameter settings are not limited to this, depending on actual needs.

Please refer to FIG. 2 to FIG. 5 . FIG. 5 is a schematic diagram of the conduction module 56 of the present embodiment. The first clamping male terminal 38 and the second clamping female terminal 40 of the voltage dynamic self-balancing energy storage device 20 are respectively disposed at opposite ends of the conduction member 31. The first clamping male terminal 38 and the second clamping female terminal 40 can be fixedly or detachably mounted on the conducting member 31, or the first clamping male terminal 38 and the second clamping female terminal 40 can be fixedly connected. The member 31 is regarded as an integrally formed conduction mechanism 30, and the electric wires formed by the conduction mechanism 30 in conjunction with other components are regarded as the conduction module 56. The conduction module 56 can be used as a voltage dynamic self The parallel connection lines between the energy storage devices 20 are balanced. The first clamping male terminal 38 may be in the shape of a plate or a column or other shape, and the second clamping female terminal 40 is a Y-like chuck whose clamping portion is plate-shaped corresponding to the first clamping male terminal 38 or Column or other shape clamping structure. The first clamping male terminal 38 of each voltage dynamic self-balancing energy storage device 20 can be inserted into the second clamping female terminal 40 of another voltage dynamic self-balancing energy storage device 20 to establish a voltage dynamic self-balancing energy storage device 20 Current transfer channel between. Since the plurality of voltage dynamic self-balancing energy storage devices 20 can be connected in series or in parallel to form an energy storage combination, the first clamping terminal 38 and the second clamping terminal 40 preferably need to increase the thickness and the clamping area thereof. Conductive force and high heat dissipation efficiency to effectively reduce the operating temperature of the energy storage combination during charging and discharging, and enhance the convenience and safety of the product. In addition, the conduction module 56 can also be applied to the series connection if it is specially designed (for example, the form in which the internal wires of the movable connection cable 54 are staggered).

Please refer to FIG. 7 and FIG. 8 . FIG. 7 and FIG. 8 are respectively schematic diagrams of the conduction module 56 ′ and the conduction module 56 ′′ according to other embodiments of the present invention. The first clamping male terminal of the foregoing embodiment. 38 is a cylindrical structure, and the second clamping terminal 40 is a cylindrical structure conforming to the cylindrical structure. In contrast, as shown in FIG. 7, the conduction module 56' will be the first clamping male terminal 38. 'The second clamping female terminal 40' is respectively disposed at two opposite ends of the conduction member 31, the first clamping terminal 38' is a plate structure, and the second clamping female terminal 40' is associated with the plate structure Corresponding structure; as shown in FIG. 8, the first clamping male terminal 38" and the second clamping female terminal 40" of the conducting module 56" are respectively disposed at opposite ends of the conducting member 31, first The clamping male terminal 38" is a wave plate structure, and the second clamping terminal 40" is a corresponding wave-shaped structure. The different shapes of the clamping terminals are intended to increase the contact area between the two in a limited space, so the clamping terminals are not limited to those described in the above embodiments, and may have any type of change depending on the design requirements.

To this end, the first clamping male terminal 38 can be a planar structure, a sheet-like structure, a circular structure, a plate-like structure or a columnar structure, or other shape structure, and the second clamping female terminal 40 is a Y-like clamp. Head, its The nip portion corresponds to a planar structure, a sheet structure, a circular structure, a plate structure or a columnar structure, or a sandwich structure of other shapes. The second clamping female terminal 40 is mainly composed of the bottom portion 42, the clamping portion 44, and the oblique guiding portion 46, but the actual structural change is not limited thereto. For example, in the form of a plate, the two ends of the clamping portion 44 are respectively connected to the bottom portion 42 and the inclined guiding portion 46; the inclined guiding portion 46 is the front end of the Y-like chuck, and the clamping portion 44 corresponds to the middle of the Y-shaped chuck. The plate-like structure provides a clamping plane that is much larger than the point or line contact nip of the conventional M-type collet. The clamping portion 44 is elastically deformable relative to the bottom portion 42 for embossing the first clamping male terminal 38 of the other voltage dynamic self-balancing energy storage device 20 by surface contact. By using the design, the contact area of the clamping portion 44 with the first clamping male terminal 38 of the other voltage dynamic self-balancing energy storage device 20 can be greatly increased, the conductive flow rate is increased, and the temperature is effectively lowered to avoid overheating. The inclined guiding portion 46 forms an outer wide and narrow opening, and can guide the first clamping male terminal 38 of the other voltage dynamic self-balancing energy storage device 20 into the second clamping female terminal 40, and is large for the clamping portion 44. The area is contacted by the contact method. In addition, the voltage dynamic self-balancing energy storage device 20 may further include a first engaging member 48 and a second engaging member 50 respectively disposed on opposite sides of the housing 22. When the two adjacent voltage dynamic self-balancing energy storage devices 20 are engaged with each other by the first engaging member 48 and the second engaging member 50, the first clamping male terminal 38 of the voltage dynamic self-balancing energy storage device 20 is simultaneously The second clamping female terminal 40 of another voltage dynamic self-balancing energy storage device 20 is inserted, and the three portions are forcedly positioned by the mechanism to ensure a stable combination of the two.

In addition to directly clamping the two voltage dynamic self-balancing energy storage devices 20 in parallel with the first clamping male terminal 38 and the second clamping female terminal 40, the present invention can also utilize the movable connecting cable 54 (or the movable plug). A plurality of voltage dynamic self-balancing energy storage devices 20 are connected in series. The movable link cable 54 or the movable plug is a series connection mechanism design. Please refer to FIG. 6. FIG. 6 is a schematic diagram of a plurality of voltage dynamic self-balancing energy storage devices 20 connected in series by a movable connecting cable 54 according to an embodiment of the present invention. The movable connecting cable 54 can be a kind of cable or plug, so the voltage dynamic self-balancing energy storage devices 20 do not need to be close together, and can move freely within the length of the movable connecting cable 54; or, the activity Connection cable 54 The first clamping male terminal 38 of any voltage dynamic self-balancing energy storage device 20 can be connected in series to the second clamping of another voltage dynamic self-balancing energy storage device 20 via the movable connecting cable 54. Female terminal 40. The two ends of the movable connecting cable 54 are respectively provided with a clamping connection structure similar to that of the first clamping male terminal 38 and the second clamping female terminal 40, that is, a series connection structure design designed as shown in the middle of FIG. As explained in the previous paragraph and the drawings. When the plurality of voltage dynamic self-balancing energy storage devices 20 are connected in series, the movable connecting cable 54 can be used independently or combined with the first clamping male terminal 38 and the second clamping female terminal 40 to facilitate moderate regulation and storage. The combination of voltage changes and increased power and/or capacity amplification requirements can effectively control temperature rise. The movable connection cable 54 may further have a conduction switch, and the user determines whether the energy storage combination system is boosted or charged and discharged in the original state by operating the conduction switch.

The voltage dynamic self-balancing energy storage device 20 selectively sets a DC one-way charging port 52, is mounted on the housing 22, and is electrically connected to the energy storage unit 32 via the protection circuit board 28. The protection circuit board 28 is electrically connected to the DC one-way charging port 52 by a third transmission line 58. The user uses the DC one-way charging port 52 to introduce the power signal from the external device into the voltage dynamic self-balancing energy storage device 20 in a one-way transmission direction; therefore, the protection circuit board 28 can detect the power signals of the three sources in total. The first source is the power signal flowing through the input terminal group 24 to the protection circuit board 28. The second source is the power signal of the external device output flowing to the protection circuit board 28 via the DC one-way charging port 52. The third source is the storage. The power unit 32 flows to the power signal of the protection circuit board 28. The protection circuit board 28 detects parameter values such as voltage and/or current of the power signals of the three sources, so as to perform flow direction change and adjustment of the power signal by using voltage control; for example, avoiding the occurrence of a circuit short circuit and the like, but not limited to this. The voltage dynamic self-balancing energy storage device 20 can be charged by the commercial power using a DC power supply device (ADAPTER). When the voltage dynamic self-balancing energy storage device 20 is charged or discharged to a preset voltage value, the relevant indicator light of the voltage dynamic self-balancing energy storage device 20 can emit a specific optical signal to remind the user to power off or self-power off, for example, The indicator light can be set for power supply in the mains, green energy active kinetic energy generator, wind power or solar power, or even the power supply to the petrochemical generator. The green indicator light of the device or the liquid crystal display panel and the power-off design of the portable energy storage device are used to prolong the service life of the voltage dynamic self-balancing energy storage device 20 and expand the use occasion; in the voltage dynamic self-balancing energy storage device 20 During use, if the voltage is lower than the preset value, the indicator light can emit another optical signal to remind the user to stop the discharge, or to start the discharge protection by protecting the circuit board. Alternatively, the voltage dynamic self-balancing energy storage device 20 can selectively match the energy storage device of the green energy active kinetic energy generator, the solar power generation device or the wind power generation device or the petroelectric generator, and is convenient for the user. Replenish and store energy in areas where there is no electricity or no electrical equipment.

In summary, this creation firstly obtains the voltage dynamic self-balancing energy storage device 20 of the same energy storage unit within the specification range such as the internal impedance coefficient through instrument detection and screening, and each voltage dynamic self-balancing energy storage device 20 can be Having a single or multiple energy storage units, the energy storage units can be connected to each other in series and/or in parallel, and the same voltage dynamic self-balancing energy storage device 20 within a plurality of impedance specifications can also be connected in series or in parallel. The energy storage combination is integrated into a large voltage dynamic self-balancing energy storage device. A conducting mechanism 30 is disposed between the input terminal group 24 and the output terminal group 26 of each of the voltage dynamic self-balancing energy storage devices 20, and a through current guiding channel is established, which can be dynamically driven according to another voltage connected to the energy storage device 20 The difference in the parameter value of the power signal of the balanced energy storage device 20 is controlled by the voltage of the protection circuit board 28 through the dynamic self-balancing platform of the conduction mechanism 30 to enter (charge) or discharge (discharge) the power signal of the energy storage unit, thereby ensuring the energy storage combination. A voltage dynamic self-balancing energy storage device 20 can share a balanced and stable voltage and is used like a single battery. Avoiding the energy storage combination during charging and discharging, the large amount of electricity is selectively reacted only to the voltage dynamic self-balancing energy storage device 20 having a lower voltage or a lower quality; the second clamp of the Y-type chuck is respectively disposed at both ends of the conduction mechanism 30 Holding the female terminal 40, and the first clamping male terminal 38 of the plate-like structure, the clamping portion 44 of the second clamping female terminal can provide a larger contact area, which is far larger than the M-shaped terminal contact surface of the prior art. And because of its special Y-shaped structure design, in addition to saving the terminal material, it still has the characteristics of easy plugging and unplugging. Therefore, the clamping terminals can effectively dissipate the temperature and reduce the temperature rise, thereby ensuring the voltage dynamic self-leveling. Balance the convenience and safety of the energy storage device.

The conductive mechanism 30 of the present invention is a new design of a conduction mechanism plus a Y-shaped surface contact terminal or a new mechanism design of a conduction module, or a use of electrical physical characteristics (ie, the power signal is from a high voltage to a low voltage) A new mechanism for dynamic self-balancing of the voltage and quantity of the voltage at the voltage, which is forced by the conduction mechanism to force the energy storage device 20 of its application to be used at any time or in use (for example, when the battery is not charged and discharged, the state of charge, and the discharge) The state of the state, the state of the side-by-side discharge, or the connection with other energy storage devices in series or in parallel), as long as the connection can be achieved, the voltage self-balancing of all the energy storage devices 20 can be achieved in a short time, as will Multiple energy storage devices are integrated into a single battery. Compared with the prior art, the present invention does not need to set an expensive electronic central control circuit, but uses the dynamic physical self-balancing characteristic of the electrical physical voltage and current induced by the conduction mechanism 30 to allow a plurality of voltage dynamic self-balancing energy storage devices 20 connected together. The voltage self-balancing physical characteristics of the voltage and the high-current current to the low-speed and high-speed flow characteristics of the voltage, so that the voltage and power of all the connected voltage self-balancing energy storage devices 20 tend to be consistent in a short time; Connected to another voltage dynamic self-balancing energy storage device 20, the voltage dynamic self-balancing energy storage device 20 can still automatically initiate a dynamic self-balancing current flow due to the through current guiding channel of the conduction mechanism 30, so as to enable new storage. All of the energy storage devices 20 that can be combined in series and/or in parallel can quickly reach a voltage balance state as if they were combined into a single large battery.

20‧‧‧Voltage dynamic self-balancing energy storage device

22‧‧‧ housing

24‧‧‧Input terminal set using the first clamping male terminal

241‧‧‧ input positive terminal

242‧‧‧ input negative terminal

26‧‧‧Using the output terminal set of the second clamping female terminal

261‧‧‧ output positive terminal

262‧‧‧ output negative end

28‧‧‧Protected circuit board

30‧‧‧Connected institutions

32‧‧‧ Energy storage unit

34‧‧‧First transmission line

36‧‧‧Second transmission line

48‧‧‧First card fittings

50‧‧‧Second card fittings

52‧‧‧DC one-way charging port

58‧‧‧ third transmission line

Claims (23)

A conduction mechanism comprising a contact mechanism plus a surface contact terminal or a conduction module thereof for serial/parallel connection between a plurality of voltage dynamic self-balancing energy storage devices, the voltage dynamic self-balancing energy storage device One of the housings has an input terminal set and an output terminal set, the conduction mechanism includes: a first clamping male terminal; and a second clamping female terminal for inserting one of the voltages to dynamically self-balance a corresponding first clamping male terminal of the energy storage device; and a conducting member, the two ends of the conducting member respectively connecting the input terminal group provided with the first clamping male terminal and the second clamping female terminal The output terminal group, the first clamping male terminal combined with the input terminal group and the conductive member of the second clamping female terminal of the output terminal group are electrically connected to the voltage dynamics via a protection circuit board voltage control An energy storage unit of one of the self-balancing energy storage devices, wherein the conduction mechanism is based on one of the voltage dynamic self-balancing energy storage devices and another voltage dynamic self-balancing energy storage device The parameter value difference of the power signal detected by the protection circuit board dynamically dynamically adjusts the voltage signal to the power signal of the one of the voltage dynamic self-balancing energy storage devices. The conduction mechanism of claim 1, wherein the power signal received by the first clamping male terminal combined with the input terminal group is directly conducted to the second clamping female terminal combined with the output terminal group via the conduction mechanism. . The conduction mechanism according to claim 1, wherein the conduction mechanism is made of high heat resistance and high conductivity And the production of materials with high power characteristics. The conduction mechanism of claim 1, wherein the number, length, width and thickness of the conduction mechanism are defined according to a preset required power of the energy storage device. The conduction mechanism of claim 1, wherein when the plurality of voltage dynamic self-balancing energy storage devices are connected, the conduction mechanism is based on the power signals of any one or more of the voltage dynamic self-balancing energy storage devices. The parameter, through the conduction mechanism, the voltage of the protection circuit board controls the dynamic self-balancing voltage current to enter or flow out the power signal having the corresponding parameter to the other voltage dynamic self-balancing energy storage device of the plurality of voltage dynamic self-balancing energy storage devices. The conduction mechanism of claim 1, wherein the second clamping female terminal coupled to the output terminal group comprises: a bottom portion; a clamping portion for pressing the other voltage dynamic self-balancing in a surface contact manner a corresponding first clamping terminal of the energy storage device, one end of the clamping portion is connected to the bottom portion, and the clamping portion is a one-sided structure, a one-piece structure or a circular structure, and the clamping portion is pressed in a surface contact manner Attaching the corresponding first clamping terminal; and a oblique guiding portion connected to the opposite end of the clamping portion for guiding the corresponding first clamping male terminal contact of the another voltage dynamic self-balancing energy storage device The clamping portion. An energy storage device capable of effectively achieving dynamic self-balancing of voltage and electricity, applying a mechanism of a contact mechanism plus a contact terminal or a conduction module thereof for designing a voltage dynamic self-balancing energy storage device connected in series and parallel, the voltage dynamic The self-balancing energy storage device includes: a housing, the housing is internally accommodating at least one energy storage unit; an input terminal group is disposed on one side of the housing; and an output terminal group is disposed on the other side of the housing, the output terminal group An input terminal group for connecting another voltage dynamic self-balancing energy storage device; and a conduction mechanism comprising a conduction member, a first clamping male terminal and a second clamping female terminal, the two ends of the conducting member respectively Connecting the input terminal group having the first clamping male terminal and the output terminal group having the second clamping female terminal, the input terminal group and the output terminal group being electrically connected via a protective circuit board through the conduction mechanism Connected to the energy storage unit, the conduction mechanism is corresponding to the difference in parameter values of the power signal detected by the voltage dynamic self-balancing energy storage device and the other voltage dynamic self-balancing energy storage device via the protection circuit board. Dynamically self-balancing the mechanism to enter or remove the power signal of the energy storage unit. The voltage dynamic self-balancing energy storage device of claim 7, wherein the input terminal group having the first clamping male terminal, the direct current one-way charging port, and the power signal received by the energy storage unit are electrically connected The mechanism is directly transmitted to the output terminal group having the second clamping female terminal, or is dynamically self-balanced to the conduction mechanism or the conduction module through the protection circuit board voltage to flow into or out of the energy storage unit to achieve the voltage dynamics. The self-balancing energy storage device continuously maintains the voltage self-balancing energy of the voltage dynamic self-balancing energy storage device and the other connected voltage dynamic self-balancing energy storage device within a specific range. . The voltage dynamic self-balancing energy storage device according to claim 7, wherein the specification of the energy storage unit is the same as the specification of the energy storage unit of one of the other voltage dynamic self-balancing energy storage devices. The voltage dynamic self-balancing energy storage device of claim 7, wherein the housing further houses a plurality of energy storage units, and the internal impedance coefficients of the energy storage units of the energy storage units are within a specific range. The voltage dynamic self-balancing energy storage device of claim 7, wherein the first clamping male terminal combined with the input terminal group comprises at least one input positive terminal and at least one input negative terminal, and the output terminal group is combined with the output terminal group The second clamping female terminal includes at least one output positive terminal and at least one output negative terminal. The voltage dynamic self-balancing energy storage device of claim 7, wherein the protection circuit board is electrically connected to the conduction mechanism and the unidirectional charging port, and is electrically connected to the energy storage unit, and the first combination of the input terminal group A clamping male terminal and the second clamping female terminal combined with the output terminal group are electrically connected to the energy storage unit via the protection circuit board. The voltage dynamic self-balancing energy storage device of claim 7, wherein the protection circuit board is electrically connected to the conduction mechanism through a first transmission line, electrically connected to the energy storage unit through a second transmission line, and through a third The transmission line is electrically connected to the unidirectional charging port for detecting the power signal of the conduction mechanism, the energy storage unit and the DC unidirectional charging port, and uses the first transmission line and the second transmission line to pass the protection circuit board The voltage control function performs charging and discharging. The voltage dynamic self-balancing energy storage device of claim 13, wherein the third transmission line is a charging dedicated line. The voltage dynamic self-balancing energy storage device of claim 7, wherein the protection circuit board is only When a single transmission line is electrically connected to the energy storage unit, it is additionally set that the maximum charging current limit that the protection circuit board must start does not exceed 0.5 C until the set saturation point is turned off, and/or the discharge current is limited to 2 C until The set discharge cutoff point is cut off. The voltage dynamic self-balancing energy storage device of claim 7, further comprising: a direct current unidirectional charging port electrically connected to the conduction mechanism and the energy storage unit via the protection circuit board. The voltage dynamic self-balancing energy storage device of claim 7, wherein the conduction mechanism is made of a material having high heat resistance, high electrical conductivity, and high power characteristics. The voltage dynamic self-balancing energy storage device of claim 7, wherein the number, length, width and thickness of the conduction mechanism are defined according to the number of the energy storage units and/or the preset required power. The voltage dynamic self-balancing energy storage device of claim 7, wherein when the voltage dynamic self-balancing energy storage device is connected to the other voltage dynamic self-balancing energy storage device, the conduction mechanism is dynamically self-balancing according to the other voltage. The power signal parameter of the energy storage device dynamically flows the power signal with the corresponding parameter according to the principle of voltage control to the energy storage unit via the voltage of the protection circuit board, or the voltage control flow from the energy storage unit through the protection circuit board The power signal of the corresponding parameter. The voltage dynamic self-balancing energy storage device of claim 7, wherein the first clamping male terminal is disposed at one end of the conducting member for inserting a corresponding second clip of the another voltage dynamic self-balancing energy storage device Holding a female terminal, the second clamping female terminal is disposed at the other opposite end of the conducting member for being inserted into a corresponding first clamping male terminal of the other voltage dynamic self-balancing energy storage device. The voltage dynamic self-balancing energy storage device of claim 7, wherein the second clamping female terminal comprises: a bottom portion; and a clamping portion for pressing the other voltage dynamic self-balancing energy storage in a surface contact manner a first clamping male terminal of the device, one end of the clamping portion is connected to the bottom portion, the clamping portion is a one-sided structure, a one-piece structure or a circular structure, and the clamping portion is pressed in a surface contact manner Corresponding to the first clamping male terminal; and a diagonal guiding portion connected to the opposite end of the clamping portion for guiding the corresponding first clamping male terminal contact of the another voltage dynamic self-balancing energy storage device The clamping portion. The voltage dynamic self-balancing energy storage device of claim 7, further comprising: a first engaging member disposed on the side of the housing; and a second engaging member disposed on the housing On the other side, a corresponding first engaging member for engaging the other voltage dynamic self-balancing energy storage device. The voltage dynamic self-balancing energy storage device of claim 7, wherein the input terminal group forms a concave structure with respect to the housing, the concave structure is for accommodating the first clamping male terminal, and is additionally used. The output terminal group of one of the voltage dynamic self-balancing energy storage devices is accommodated, and is combined with a second clamping female terminal built in the output terminal group of the other voltage dynamic self-balancing energy storage device.