JP7159370B2 - capacitor module - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a capacitor module, and more particularly, to a capacitor module capable of stably sensing heat generation of capacitor cells.

A capacitor is a typical energy storage device that stores electrical energy. Among these capacitors, Ultra-Capacitor (UC) has high efficiency, semi-permanent life, and rapid charge/discharge characteristics. It is forming a market as an energy storage device that can supplement the voltage problem.

Based on these advantages, ultracapacitors can be used not only as auxiliary power sources for mobile devices such as mobile phones, tablet PCs, and laptops, but also as power sources for electric vehicles, hybrid vehicles, and solar cells, which require high capacity. It is also widely used as a main power source or an auxiliary power source for road indicator lights at night, uninterruptible power supply (UPS, Uninterrupted Power Supply) and the like.

Since the voltage of one such ultracapacitor is only 3V, an ultracapacitor module is formed by connecting a plurality of ultracapacitors as unit cells in series or parallel for use in high voltage applications. .

The conventional ultracapacitor module has a problem in that it is difficult to check whether the temperature of each ultracapacitor corresponding to a unit cell deviates from a preset reference temperature.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a capacitor module capable of stably sensing and managing the degree of heat generation of a capacitor cell.

To achieve the above objects, a capacitor module according to an embodiment of the present invention includes a housing, a plurality of capacitor cells disposed inside the housing, and a pair of wires separated from each other and a pair of wires enclosing a pair of wires. The capacitor includes a molding, and includes a first sensing unit that contacts each of the plurality of capacitor cells and senses heat generation of the capacitor cells.

Also, the plurality of capacitor cells are arranged in a plurality of rows and a plurality of columns on a plane, and the first sensing units are arranged between the rows or between the columns and extend along the rows or columns.

In addition, the capacitor cells have a cylindrical shape having a bottom surface, a top surface and a side surface, and the first sensing unit includes the side surfaces of the capacitor cells in the first row among the plurality of rows and the capacitor cells in the second row that are in contact with the first row. It is characterized by being inserted between each side.

In addition, the apparatus further includes a second sensing unit disposed on the plurality of capacitor cells and sensing temperature due to heat generated by the capacitor cells.

Also, the plurality of capacitor cells are divided into a plurality of groups each including a predetermined number of capacitor cells, and the second sensing units are arranged in each of the plurality of groups.

The controller further includes a controller for generating an alarm signal by the first sensor and the second sensor, the controller having a first port for receiving the signal of the first sensor and a second port for receiving the signal of the second sensor. , and a first computation unit for generating an alarm signal from at least one of the signals of the first port and the signal of the second port.

The controller may further include a third port for connecting the additional capacitor module and a signal generator for providing a predetermined signal to the third port.

According to the present invention, it is possible to stably sense the degree of heat generation of each of a plurality of capacitor cells at low cost.

Also, measuring the heat generation of multiple capacitors may be measured in parallel to increase stability.

1 is a diagram illustrating a capacitor module according to an embodiment of the present invention; FIG. 2 is a plan view schematically illustrating the capacitor module illustrated in FIG. 1; FIG. 3 is a diagram illustrating another embodiment of the first sensing unit illustrated in FIG. 2; FIG. FIG. 3 is a diagram illustrating another embodiment of the capacitor module illustrated in FIG. 2; FIG. FIG. 3 is a diagram illustrating an embodiment of the controller illustrated in FIG. 2; FIG. FIG. 6 is a diagram illustrating another embodiment of the controller illustrated in FIG. 5; FIG.

A capacitor module 1 according to a preferred embodiment of the present invention will now be described in detail.

FIG. 1 is a drawing illustrating a capacitor module 1 according to an embodiment of the present invention, and FIG. 2 is a plan view schematically illustrating the capacitor module 1 illustrated in FIG.

1 and 2, a capacitor module 1 according to one embodiment of the present invention includes a housing 10, a plurality of capacitor cells, and a plurality of capacitor cells to increase the cost and space utility required to sense the heat generation of the capacitor cells 20. 20 and a first sensing portion 30 . A capacitor cell 20 is mounted on a PCB substrate. The housing 10 accommodates a PCB board, a plurality of capacitor cells 20 and a first sensing portion 30 . Capacitor cell 20 may be placed upside down on a PCB substrate. Capacitor cell 20 may be an ultracapacitor cell.

The first sensing part 30 may include a first thermal wire, a second thermal wire and a skin. The first thermal wire and the second thermal wire are twisted together along their lengths. The first thermal lead includes a first current carrying line and a first fusion coating. The first conducting line is a conductive metal. A first melting coating surrounds the first current carrying line and melts above a predetermined temperature. The second heat sensitive wire also includes a second current carrying line and a second fusion coating similar to the first heat sensitive wire. The function for this is the same as the first thermal lead.

The first heat-sensitive wire and the second heat-sensitive wire are connected to a detection circuit (not shown) of the controller 50 capable of sensing the heating state. In one embodiment, when the first and second molten coatings are heated above a predetermined temperature to melt, the first and second molten coatings are shorted together. At this time, the detection circuit can detect the short circuit between the first conducting line and the second conducting line. Also, the detection circuit can detect disconnection of the first heat-sensitive lead or the second heat-sensitive lead. The controller 50 can detect heat generation of the capacitor cell 20 through the detection circuit.

It is recommended for safety and performance aspects that the capacitor cell 20 operates at 65 degrees Celsius or less. The first sensing portion 30 can be shorted around 80 degrees Celsius. Therefore, the first sensing unit 30 can sense overheating of the capacitor cell 20 . The first sensing part 30 is installed to contact each of the plurality of capacitor cells 20 at least once.

As an example, the plurality of capacitor cells 20 are arranged in a plurality of rows (C1-C4) and a plurality of columns (R1-R6) on a plane (on the PCB substrate). Here, the first sensing units 30 are arranged between rows or columns. Also, the first sensing portion 30 extends along rows or columns. Accordingly, the first sensing unit 30 may contact all the capacitor cells 20 on both sides.

Capacitor cell 20 is cylindrical and has a bottom surface, a top surface S and side surfaces. At this time, the first sensing unit 30 is inserted between the capacitor cells 20 of the first row and the capacitor cells 20 of the second row adjacent to the first row among a plurality of rows on a plane (on the PCB substrate). This allows the first sensing portion 30 extending along the row to contact all of the capacitor cells 20 on both sides. Since the capacitor cell 20 is made of aluminum, heat generated from the capacitor cell 20 sufficiently affects the first sensing part 30 . Since the first sensing part 30 is inserted between the capacitor cells 20 , it is arranged to contact the side surfaces of the capacitor cells 20 . Preferably, the first sensing part 30 can only contact the side of the capacitor cell 20 .

Meanwhile, the first sensing unit 30 may be inserted between the capacitor cells 20 of the first column and the capacitor cells 20 of the second column adjacent to the first column among the plurality of columns. Also, the first sensing units 30 may be interposed between the columns and rows of the capacitor cells 20 .

Also, the diameter of the first sensing part 30 may be equal to or greater than the distance between adjacent capacitor cells 20 . That is, the first sensing part 30 is tightly fitted between adjacent capacitor cells 20 . Accordingly, the first sensing unit 30 may be fixed between the capacitor cells 20 forming the first row and the capacitor cells 20 forming the second row. The capacitor module 1 of the present invention is installed on an arm of a robot or the like. Therefore, in the case of the present invention, the coupling force between the capacitor cell 20 and the first sensing part 30 can be stably secured.

FIG. 3 shows another embodiment of the first sensing unit 30 shown in FIG. 2, and FIG. 4 shows another embodiment of the capacitor module 1 shown in FIG.

3 and 4, the capacitor module 1 according to one embodiment of the present invention may include a plurality of first sensing units 30. As shown in FIG. When the plurality of capacitor cells 20 are arranged in multiple rows (C1-C6) and multiple columns (R1-R4), multiple first sensing units 30 can be arranged. In this case, the first sensing unit 30 is also arranged between one row (column) of capacitor cells 20 and another adjacent row (column) of capacitor cells 20 . Also, one of the plurality of first sensing units 30 and another one may contact the same capacitor cell 20 .

Also, the capacitor module 1 according to an embodiment of the present invention may further include a second sensing unit 40 . The second sensing part 40 is disposed on the plurality of capacitor cells 20 and can sense the temperature generated by the capacitor cells 20 . When the second sensing part 40 is mounted on the top surface of the PCB board, cell leakage liquid generated during long-term use of the capacitor cell 20 may corrode the circuit pattern formed on the PCB board. This causes malfunction of the second sensing unit 40 . The second sensing unit 40 of the present invention is arranged on top of the plurality of capacitor cells 20 mounted on the PCB substrate. Therefore, malfunction due to cell leakage is prevented. The second sensor 40 may include a PTC thermistor (Positive temperature coefficient thermistor) and an NTC thermistor (Negative temperature coefficient thermistor). For a PTC thermistor, an increase in temperature causes an increase in resistance. For NTC thermistors, a decrease in temperature causes a decrease in resistance. Therefore, the second sensing unit 40 can generate a predetermined signal at a preset temperature value (range).

As an example, the second sensing units 40 are arranged in groups G1 to G4 each including a plurality of capacitor cells 20 . A plurality of capacitor cells 20 may be classified into groups that include a predetermined number of capacitor cells 20 . That is, the plurality of capacitor cells 20 can be divided into a plurality of groups G1-G4. The second sensing units 40 are arranged in each of a plurality of groups G1 to G4. Since the second sensing part 40, which is a temperature sensor, is expensive, there is a problem in that manufacturing costs increase when a plurality of sensors are used. Therefore, by arranging the second sensing units 40 in a plurality of groups G1 to G4 that divide the plurality of capacitor cells 20, it is possible to sense and check the temperature of the entire surface of the plurality of capacitor cells 20 on a plane while reducing costs. can.

Also, the second sensing unit 40 is disposed above the plurality of capacitor cells 20 . That is, the second sensing part 40 is arranged to be separated from the PCB substrate with the plurality of capacitor cells 20 interposed therebetween. Accordingly, it is possible to avoid the spacing and spatial restrictions between the capacitor cells 20 due to the placement of the second sensing part 40, which is the temperature sensor, on the PCB substrate.

FIG. 5 is a diagram illustrating one embodiment of the controller 50 shown in FIG. 2, and FIG. 6 is a diagram illustrating another embodiment of the controller 50 shown in FIG.

Referring to FIGS. 4-6, the controller 50 can generate an alarm signal by the first sensing portion 30 and the second sensing portion 40. FIG. The controller 50 can include a first port 500 , a second port 510 and a first computing unit 520 . The first port 500 is connected to the first sensing unit 30 to receive the signal of the first sensing unit 30 . The second port 510 is connected to the second sensing unit 40 to receive the signal of the second sensing unit 40 . The first calculator 520 may generate an alarm signal based on at least one of the signals of the first port 500 and the second port 510 . Here, the signal from the second sensor 40 may be a signal corresponding to a preset temperature value (range). As a result, the heat generation of the capacitor 20 can be double observed and managed.

Meanwhile, the controller 50 may further include a third port 530 and a signal generator 540 . A third port 530 may be connected to an additional capacitor module 1 . Therefore, heat generation of the capacitor cells 20 can be stably sensed while increasing the capacity of the capacitor module 1 . A plurality of additional capacitor modules 1 may be connected.

The signal generator 540 is connected to the third port 530 and provides a predetermined signal to the third port 530 . The signal generator 540 can provide a first signal (eg, '0' or 'LOW value') or a second signal (eg, '1' or 'HIGH value') to the third port 530 . For example, the signal generator 540 may output the second signal (HIGH value) when the additional capacitor module 1 is not connected to the third port 530 . This makes it possible not to affect the generation of alarms. For this purpose, the signal generator 540 may include a pull-up resistor (PULL-UP RESISTOR). Also, the signal generator 540 may further include a transistor (not shown). Meanwhile, when an abnormal signal due to heat generation of the capacitor cell 20 is input to the third port 530 from the additional capacitor module 1 connected to the third port 530, the first signal may be provided to generate an alarm.

Meanwhile, the controller 50 further includes a first auxiliary arithmetic unit 521 . The first auxiliary operation unit 521 is connected to the first operation unit 520 and the plurality of first ports 500 . The first auxiliary computing unit 521 provides a signal for generating an alarm signal to the first computing unit 520 when a signal (short circuit signal) is input from at least one first sensing unit 30 among the plurality of first sensing units 30 . .

Also, the first auxiliary operation unit 521 is connected to the first operation unit 520 and the plurality of second ports 510 . The first auxiliary calculation unit 521 outputs a signal for generating an alarm signal when at least one of the second sensing units 40 among the plurality of second sensing units 40 receives a signal (a signal indicating that the preset temperature is reached). It is provided to the calculation unit 520 . One or two or more first auxiliary operation units 521 may be arranged. When there is one first auxiliary operation unit 521 , the first auxiliary operation unit 521 may be connected to a plurality of first sensing units 30 and a plurality of second sensing units 40 .

Although the invention made by the present inventors has been specifically described with reference to the above embodiments, it goes without saying that the present invention is not limited to the above embodiments and can be variously modified without departing from the gist of the invention.

1: Capacitor module 10: Housing 20: Capacitor cell 30: First sensing unit 40: Second sensing unit 50: Controller 500: First port 510: Second port 520: First computing unit 530: Third port 540: Signal generator

Claims (3)

housing;
a plurality of capacitor cells positioned inside the housing;
a first sensing unit including a pair of wires spaced apart from each other and a sheath surrounding the pair of wires, contacting each of the plurality of capacitor cells to sense heat generation of the capacitor cells;
a second sensing unit disposed on the plurality of capacitor cells and sensing temperature due to heat generation of the capacitor cells ; and
a controller for generating an alarm signal by the first sensor and the second sensor;
A plurality of capacitor cells are arranged in a plurality of rows and a plurality of columns on a plane,
the first sensing units are interposed between rows or columns of capacitors and extend along the rows or columns;
The controller is
a first port for receiving the signal of the first sensor;
a second port for receiving the signal of the second sensor;
a first computing unit that generates an alarm signal from at least one of the signals of the first port and the signal of the second port;
a third port for connecting additional capacitor modules; and
a signal generator that provides a predetermined signal to the third port;
A capacitor module in which the signal generator includes a pull-up resistor . the capacitor cell is cylindrical having a bottom surface, a top surface and side surfaces;
2. The method according to claim 1, wherein the first sensing unit is inserted between side surfaces of the capacitor cells in the first row and side surfaces of the capacitor cells in the second row adjacent to the first row among the plurality of rows on the plane. capacitor module. the plurality of capacitor cells are divided into a plurality of groups each including a predetermined number of capacitor cells;
The capacitor module of claim 1, wherein the second sensing units are arranged in each of the plurality of groups.

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