KR102711056B1 - Battery pack that can eliminate latch-up phenomenon - Google Patents

Abstract

The present invention relates to a battery pack capable of resolving a latch-up phenomenon, and more specifically, to a battery pack capable of resolving a latch-up phenomenon by implementing a power reset of a main IC according to the temperature of a charging FET through a PTC (Positive Temperature Coefficient-thermistor), thereby restoring a main IC to a normal state.

Description

Battery pack that can eliminate latch-up phenomenon {Battery pack that can eliminate latch-up phenomenon}

The present invention relates to a battery pack capable of resolving a latch-up phenomenon, and more specifically, to a battery pack capable of resolving a latch-up phenomenon by implementing a main IC power reset through a PTC (Positive Temperature Coefficient-thermistor).

Unlike non-rechargeable primary batteries, rechargeable secondary batteries are widely used in a variety of fields, including small high-tech electronic devices such as smartphones, laptop computers, and PDAs, as well as electric vehicles and energy storage systems.

Such electronic devices generally include an interface section for connection with an external device, and can, for example, receive power for charging a battery by connecting to a charger through the interface section.

Meanwhile, the interface part generally uses a mechanical contact method, and when an external device such as a charger is connected to the interface part using the contact method, an electrical overstress (EOS) may occur momentarily. The electrical overstress (EOS) may damage electronic components such as the main IC, and in this case, a latch-up phenomenon may occur in key electronic components such as the main IC.

The above main IC is a chip that plays an overall control role to ensure stable operation of the battery by controlling the battery's charging/discharging operations, etc. If a latch-up phenomenon occurs in this main IC, the control role cannot be performed stably, so if it continues, dangerous problems such as damage to the battery may occur, and the lifespan of the battery may also be reduced.

Therefore, when a latch-up phenomenon occurs, it is necessary to take measures to quickly restore it to a normal state so that the battery can operate stably. As a method of resolving the latch-up phenomenon and restoring it to a normal state, for example, when a latch-up phenomenon occurs in a main IC, it is possible to restore it to a normal state by resetting the power of the main IC. However, since this was possible through the configuration of a separate additional circuit, there was a problem of increased cost.

(Patent Document 1) KR10-0478358 B1

The present invention seeks to solve the above-described problems, and provides a method for eliminating the latch-up phenomenon by implementing a power reset of a main IC through a PTC (Positive Temperature Coefficient-thermistor) without the need for configuring a separate additional circuit, and a battery pack using the same.

A battery pack capable of resolving a latch-up phenomenon according to the present invention comprises: one or more battery cells; a charging FET that controls the flow of a charging current of the battery cells; a discharging FET that controls the flow of a discharging current of the battery cells; a main IC that operates by receiving driving power from the battery cells and controls the charging FET and the discharging FET; and a power cutoff unit that is provided on a current path flowing from the battery cells to the main IC and controls the supply of driving power to the main IC.

Here, the power cutoff unit is characterized by detecting the temperature of the charging FET and controlling the current flowing from the battery cells to the main IC according to the detected temperature.

Specifically, the power cutoff unit is characterized by completely cutting off the current flowing from the battery cells to the main IC when the temperature of the charging FET exceeds a predetermined reference temperature, thereby turning off the power of the main IC.

Accordingly, when the power of the main IC is cut off by the power cutoff unit, the charging FET and the discharging FET are turned off.

In addition, the power cutoff unit is characterized in that, if the temperature of the charging FET is detected to be lower than a predetermined reference temperature after a predetermined time after the power of the main IC is cut off, the current supply flowing from the battery cells to the main IC is resumed to turn on the power of the main IC.

In addition, the power cutoff unit is characterized by being a PTC (Positive Temperature Coefficient-thermistor).

The method for resetting the power of the main IC in the battery pack according to the present invention as described above is characterized by comprising: a temperature detection step for detecting the temperature of the charging FET in the power cutoff unit; a driving power supply cutoff step for completely cutting off the current flowing from the battery cells to the main IC when the temperature detected through the temperature detection step in the power cutoff unit becomes higher than a predetermined reference temperature, thereby cutting off the driving power supply of the main IC; a FET off step for turning off the charging FET and the discharging FET as the power of the main IC is cut off through the driving power supply cutoff step; a temperature recovery step for recovering the temperature of the charging FET after a predetermined time after the charging FET and the discharging FET are turned off through the FET off step; a driving power supply resumption step for resuming the driving power supply of the main IC by allowing the power cutoff unit to normally flow current from the battery cells to the main IC when the temperature of the charging FET, the temperature of which has been recovered through the temperature recovery step in the power cutoff unit, becomes lower than a predetermined reference temperature.

Here, the main IC is characterized by being reset and operating normally through the driving power supply resumption step.

Meanwhile, the battery pack according to the present invention is characterized as a power source for a device including a mobile phone, a wearable electronic device, a laptop, or an electric vehicle.

The present invention is cost-effective by restoring the latch-up phenomenon to normal by implementing a power reset of the main IC through a PTC (Positive Temperature Coefficient-thermistor) without the need for configuring a separate additional circuit.

Furthermore, by resolving the latch-up phenomenon and restoring the main IC to normal, the stability of the battery pack can be improved and its service life can be extended.

Figure 1 is a block diagram schematically showing a battery pack according to the present invention.
Figure 2 is a portion of a circuit diagram illustrating a problem caused by the latch-up phenomenon.
FIG. 3 is a flowchart schematically illustrating steps for implementing power reset of a main IC in a battery pack according to the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are assigned similar reference numerals throughout the specification.

Terms including ordinal numbers such as first, second, etc. may be used to describe various components, but the components are not limited by the terms. The terms are only used for the purpose of distinguishing one component from another. For example, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component, without departing from the scope of the present invention. The terminology used in this application is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly indicates otherwise.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only the case where it is “directly connected” but also the case where it is “electrically connected” with another element in between. Also, when a part is said to “include” a certain component, this does not mean that other components are excluded, but that other components can be included, unless specifically stated to the contrary. The terms “step of doing” or “step of” used throughout the specification do not mean “step for.”

The terms used in the present invention are selected from the most widely used general terms possible while considering the functions of the present invention, but they may vary depending on the intention of engineers working in the relevant field, precedents, the emergence of new technologies, etc. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meanings thereof will be described in detail in the description of the relevant invention. Therefore, the terms used in the present invention should be defined based on the meanings of the terms and the overall contents of the present invention, rather than simply the names of the terms.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1. Battery pack (100) capable of resolving latch-up phenomenon according to the present invention

FIG. 1 is a block diagram schematically showing the configuration of a battery pack according to the present invention. The battery pack according to the present invention will be described with reference to FIG. 1.

1.1. Battery cell (110)

The battery pack (100) of the present invention includes one or more battery cells (110) connected in series or in parallel. The battery cells (110) supply driving power to a main IC (140) to be described later.

1.2. Charging FET (120)

The charging FET (120) is a component that controls the flow of charging current of the battery cells (110). Specifically, when an external system, such as a mobile phone or laptop, connected to the battery pack (100) is connected to the charger, it is a component that controls the flow of charging current supplied from the charger to the battery cells (110). The charging FET (120) can be turned on/off by the control of the main IC (140) described below to control the flow of charging current.

1.3. Discharge FET (130)

The discharge FET (130) is a configuration that controls the flow of discharge current of the battery cells (110). Specifically, it is a configuration that controls the flow of discharge current supplied from the battery cells (110) to an external system, such as a mobile phone or laptop, connected to the battery pack (100), and, like the charging FET (120) described above, can control the flow of discharge current by turning it on/off under the control of the main IC (140) described later.

1.4. Main IC (140)

The main IC (140) is a component that controls the overall operation so that the battery pack (100) can be operated stably. As described above, the main IC (140) receives driving power from the battery cells (110) and operates, and controls the on/off operation of the charging FET (120) and the discharging FET (130) to control the charging/discharging operation of the battery cells. If the driving power is not supplied from the battery cells (110) and the power of the main IC (140) is cut off, the charging FET (120) and the discharging FET (130) are both turned off, so that the charging/discharging operation does not proceed.

1.5. Power cutoff (150)

The power cutoff unit (150) is configured to cut off the power for driving the main IC (140), and can detect the temperature of the charging FET (120) and cut off the driving power of the main IC (140) accordingly. Specifically, the power cutoff unit (150) is configured with a PTC (Positive Temperature Coefficient-thermistor). The power cutoff unit (150) made of the PTC (Positive Temperature Coefficient-thermistor) can be provided at a position where the temperature of the charging FET (120) can be detected on the current path flowing from the battery cells (110) to the main IC (140). Accordingly, by detecting the temperature of the charging FET (120), the resistance can be varied according to the detected temperature, thereby controlling the current flowing from the battery cells (110) to the main IC (140).

Here, the principle of application of the power cutoff unit (150) will be explained. First, in the normal state of the battery pack (100), the charging FET (120) is off and the discharging FET (130) is on. When discharging starts here, the charging FET (120) is off, but as shown in FIG. 2, discharging is possible through the parasitic diode of the charging FET (120), so that current flows in the discharging direction (left->right). When current flows, the main IC (140) detects this and turns on the charging FET (120) to control the discharging to proceed normally. Here, the normal state means a state in which no charging/discharging is in progress while the battery pack (100) is connected to an external system such as a mobile phone or laptop.

However, when a latch-up phenomenon occurs in the main IC (140) due to electrical overstress (EOS), the main IC (140) does not operate normally, so the charging FET (120) does not turn on and current continues to flow through the parasitic diode, which eventually causes heat generation in the charging FET (120) due to the resistance of the parasitic diode. If heat generation continues in the charging FET (120) like this, it causes damage to the charging FET (120), which may have a negative effect on the battery pack (100). Therefore, it is necessary to quickly resolve the latch-up phenomenon that occurred in the main IC (140) and restore it to normal. The latch-up phenomenon is generally restored to normal by resetting the power of the main IC (140).

Accordingly, the present invention utilizes this principle to configure a power cutoff unit (150) that cuts off the driving power of the main IC (140) depending on the temperature of the charging FET (120), thereby implementing a power reset of the main IC (140) in which a latch-up phenomenon has occurred, thereby returning the main IC (140) to normal.

That is, the power cutoff unit (150) made of a PTC (Positive Temperature Coefficient-thermistor) increases the resistance of the power cutoff unit (150) as the temperature of the charging FET (120) increases, thereby reducing the current flowing from the battery cells (110) to the main IC (140), and eventually, when the temperature of the charging FET (120) becomes higher than a predetermined reference temperature, the current flow from the battery cells (110) to the main IC (140) is cut off, thereby cutting off the driving power of the main IC (140). Accordingly, since the power of the main IC (140) is cut off when heat is generated in the charging FET (120) above a predetermined reference temperature by the power cutoff unit (150), the charging FET (120) and the discharging FET (130) also do not operate, and accordingly, since the discharging operation through the charging/discharging FETs (120, 130) no longer proceeds, discharging through the parasitic diode of the charging FET (120) does not occur, and thus the discharging of the charging FET (120) does not occur.

In this state, the temperature of the charging FET (120) gradually decreases over time, and accordingly, the resistance of the power cutoff unit (150) also decreases, allowing the current flowing from the battery cells (110) to the main IC (140) to flow normally. Accordingly, when the temperature of the charging FET (120) becomes lower than a predetermined reference temperature, the main IC (140) can operate by normally receiving driving power from the battery cells (110) by the power cutoff unit (150).

In this way, by implementing a power reset of the main IC (140) according to the temperature of the charging FET (120) through the power cutoff unit (150), the latch-up phenomenon occurring in the main IC (140) can be resolved and restored to normal, thereby enabling stable operation of the battery pack (100).

2. Method for resolving latch-up phenomenon of battery pack according to the present invention

FIG. 3 is a block diagram schematically illustrating a step for resolving a latch-up phenomenon by implementing a power reset of a main IC in a battery pack according to the present invention.

2.1. Temperature detection stage (S100)

The temperature detection step is a step of detecting the temperature of the charging FET (120) in the power cutoff unit (150) provided on the path through which the driving current flows from the battery cell (110) to the main IC (140). As described above, the power cutoff unit (150) is provided at a position where the temperature of the charging FET (120) can be detected on the path through which the driving current flows from the battery cell (110) to the main IC (140), and thus the temperature of the charging FET (120) can be detected.

2.2. Driving power supply cut-off stage (S200)

The driving power supply cut-off step is a step in which the driving current flowing from the battery cells (110) to the main IC (140) is cut off as the temperature of the charging FET (120) detected through the temperature detection step (S100) in the power cut-off unit (150) rises, thereby cutting off the supply of driving power to the main IC (140).

Specifically, as described above, the power cutoff unit (150) is configured with a PTC (Positive Temperature Coefficient-thermistor), and the resistance can be varied according to the temperature of the charging FET (120) detected through the temperature detection step (S100), thereby controlling the driving current flowing from the battery cells (110) to the main IC (140).

As the temperature of the charging FET (120) detected through the temperature detection step (S100) increases, the power cutoff unit (150) increases in resistance to reduce the current flowing from the battery cells (110) to the main IC (140), and when the temperature of the charging FET (120) detected becomes higher than a predetermined reference temperature, the power cutoff unit (150) can completely cut off the driving current flowing from the battery cells (110) to the main IC (140). Accordingly, the main IC (140) cannot receive current from the battery cells (110) and power is cut off, and as the power of the main IC (140) is cut off, the charging FET (120) and the discharging FET (130) are turned off.

Here, in the present invention, the case where the temperature of the charging FET (120) increases refers to a state in which a latch-up phenomenon occurs in the main IC (140) due to electrical overstress (EOS). When a latch-up phenomenon occurs in the main IC (140), the main IC (140) does not operate normally, so that it cannot detect the current flowing through the parasitic diode of the charging FET (120) and control the charging FET (120) to be turned on so that normal discharge can proceed. Therefore, a situation occurs in which current continues to flow through the parasitic diode while the charging FET (120) is off, and as this situation continues, heat is generated in the charging FET (120) due to the resistance of the parasitic diode. Accordingly, the temperature of the charging FET (120) increases, and the power cutoff unit (150) detects the temperature of the charging FET (120) through the temperature detection step (S100), and when the temperature exceeds a predetermined standard, the current flowing from the battery cells (110) to the main IC (140) is completely cut off, thereby performing the driving power supply cutoff step (S200) to cut off the driving power supply of the main IC (140).

Through the above driving power supply cut-off step (S200), the power of the main IC (140) is cut off, and accordingly, the charging FET (120) and the discharging FET (130) are turned off, so that the operation of flowing current (discharging) through the parasitic diode of the charging FET (120) does not occur.

2.3. FET off stage (S300)

The FET off stage is a stage in which the charging FET (120) and the discharging FET (130) are turned off as the power of the main IC (140) is cut off through the driving power supply cut-off stage (S200). Since the main IC (140) is configured to control the operation of the charging FET (120) and the discharging FET (130), when the power of the main IC (140) is cut off, the voltage for turning on the charging FET (120) and the discharging FET (130) is not output, so the charging FET (120) and the discharging FET (130) are automatically turned off. Accordingly, since the discharge operation no longer proceeds, the heat generated by the current flow through the parasitic diode of the charging FET (120) stops, and as time passes, the temperature of the charging FET (120), which had risen above a predetermined reference temperature, gradually decreases, and can be recovered to a normal temperature (below a predetermined temperature reference) through a temperature recovery step (S400) described later.

2.4. Temperature recovery stage (S400)

The temperature recovery step is a step in which the temperature of the charging FET (120) is restored to normal by turning off the charging FET (120) and the discharging FET (130) as in the FET off step (S300) when the power of the main IC (140) is cut off through the driving power supply cut-off step (S200). Specifically, the charging FET (120) and the discharging FET (130) are turned off when the power of the main IC (140) is cut off, and thus the discharging operation no longer proceeds, so that no current flows through the parasitic diode and no heat is generated in the charging FET (120). Therefore, the temperature of the charging FET (120) is gradually restored to normal over time and can be restored to a state below a predetermined reference temperature.

2.5. Power supply resumption step (S500)

The driving power supply resumption step is a step in which, as the temperature of the charging FET (120) recovers to a predetermined reference temperature through the temperature recovery step (S400), the power cut-off unit (150) detects this and resumes the supply of driving power from the battery cells (110) to the main IC (140) so that the main IC (140) can operate normally.

As the temperature of the charging FET (120) decreases through the above temperature recovery step (S500), the resistance of the power cutoff unit (150) that detects the temperature of the charging FET (120) also decreases. Accordingly, the current flowing from the battery cells (110) to the main IC (140) gradually increases, and as the charging FET (120) reaches a predetermined reference temperature state, the power cutoff unit (150) can supply the current to the main IC (140) by allowing the current to flow normally from the battery cells (110) to the main IC (140). Accordingly, the main IC (140) can receive driving power from the current applied from the battery cells (110) and operate normally again. In other words, the power reset of the main IC (140) is implemented.

As described above, the latch-up phenomenon can be resolved by resetting the power of the main IC (140) and returning it to a normal state. Therefore, by resetting the power of the main IC (140) through S100 to S400, the latch-up phenomenon can be resolved and the main IC (140) can be returned to a normal state.

In this way, the present invention can improve efficiency in terms of cost by implementing power reset of the main IC (140) through a power cutoff unit (150) composed of a PTC (Positive Temperature Coefficient-thermistor) without configuring a separate additional circuit, thereby eliminating the latch-up phenomenon and restoring it to a normal state. Accordingly, it is possible to provide a battery pack with improved stability at an efficient cost.

Meanwhile, although the technical idea of the present invention has been specifically described according to the above embodiments, it should be noted that the above embodiments are for the purpose of explanation and not for the purpose of limitation. In addition, those skilled in the art in the technical field of the present invention will be able to understand that various embodiments are possible within the scope of the technical idea of the present invention.

100: Battery Pack
110: Battery Cell
120: Charging FET
130: Discharge FET
140: Main IC
150: Power cutoff

Claims (10)

One or more battery cells;
A charging FET that controls the flow of charging current of the above battery cells;
A discharge FET that controls the flow of discharge current of the above battery cells;
A main IC that operates by receiving driving power from the above battery cells and controls the charging FET and the discharging FET;
Provided on the current path flowing from the above battery cells to the main IC,
A power cutoff unit that controls the driving power supply of the above main IC;
It consists of, including:
The above power cutoff part,
When the temperature of the charging FET exceeds a predetermined reference temperature, the current flowing from the battery cells to the main IC is blocked, thereby turning off the power of the main IC.
A battery pack that, when the temperature of the charging FET is detected to be lower than a predetermined reference temperature after a predetermined period of time after the power of the main IC is cut off, resumes the supply of current flowing from the battery cells to the main IC, thereby turning on the power of the main IC and resetting the main IC. In the first paragraph,
The above power cutoff part,
A battery pack characterized in that it detects the temperature of the charging FET and controls the current flowing from the battery cells to the main IC according to the detected temperature. delete In the first paragraph,
A battery pack characterized in that when the power of the main IC is cut off by the power cutoff unit, the charging FET and the discharging FET are turned off. delete In the first paragraph,
A battery pack, characterized in that the power cut-off unit is a PTC (Positive Temperature Coefficient-thermistor). A method for resetting the power of a main IC in a battery pack according to any one of claims 1, 2, 4, and 6,
In the above power cutoff section, a temperature detection step for detecting the temperature of the charging FET;
In the above power cut-off unit, when the temperature detected through the temperature detection step becomes higher than a predetermined reference temperature, a driving power supply cut-off step for completely cutting off the current flowing from the battery cells to the main IC, thereby cutting off the driving power supply of the main IC;
As the power of the main IC is cut off through the above driving power supply cut-off step, the charging FET and the discharging FET are turned off, which is called the FET off step;
A temperature recovery step in which the temperature of the charging FET is recovered after a predetermined period of time after the charging FET and the discharging FET are turned off through the FET off step;
In the above power cutoff unit, when the temperature of the charging FET, whose temperature has been recovered through the temperature recovery step, becomes lower than a predetermined reference temperature, the power cutoff unit resumes the supply of driving power to the main IC by allowing current to flow normally from the battery cells to the main IC, thereby resetting the power of the main IC;
A main IC power reset method characterized by comprising: delete A device comprising a battery pack according to any one of claims 1, 2, 4, and 6. In Article 9,
A device characterized in that the above device is a mobile phone, a wearable electronic device, a laptop, or an electric vehicle.

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