JP2019012614A - Monitoring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a monitoring device in which an increase in the number of parts is suppressed. SOLUTION: A monitoring unit 10 for monitoring the voltage of a plurality of battery cells 220 connected in series, a wiring unit 30 for electrically connecting the monitoring unit and electrode terminals 221, 222 of the battery cells, a monitoring unit and wiring. Noise removal elements 12 and 60 provided on at least one of the portions, and the wiring portion includes a flexible substrate 40 having flexibility and a wiring pattern 50 formed on the flexible substrate, The wiring pattern has a connection pattern 51 for connecting the battery cells and the monitoring section, and a solid pattern 52 for noise suppression. The flexible substrate has a connection region 44 in which the connection pattern is formed and a solid pattern. The solid substrate 45 is formed, and the flexible substrate is bendable with respect to at least one of the connection region and the monitoring unit so that at least one of the connection region and the monitoring unit is covered by the solid region. [Selection diagram] Fig. 4

Description

  The disclosure of the present specification relates to a battery cell monitoring device.

  As shown in Patent Document 1, a battery module including a single battery group in which a plurality of single batteries are arranged and a battery wiring module attached to the single battery group is known.

  The battery wiring module includes a plurality of bus bars, a flexible printed circuit board, and a connector. The flexible printed board includes a plurality of voltage detection lines for detecting the voltage of each unit cell. The plurality of voltage detection lines connect the bus bar and the connector. The connector is connected to the battery ECU.

JP 2017-27831 A

  As described above, the battery wiring module outputs the voltage of each unit cell of the unit cell group to the battery ECU via the bus bar, the voltage detection line, and the connector. Therefore, for example, when noise is input to the voltage detection line, the voltage detection accuracy may be reduced. On the other hand, it is also conceivable to separately prepare a shielding member for noise countermeasures, thereby suppressing noise input. However, in this case, there is a problem that the number of parts increases.

  Therefore, an object of the present disclosure is to provide a monitoring device in which an increase in the number of parts is suppressed.

One of the disclosures is a monitoring unit (10) for monitoring voltages of a plurality of battery cells (220) connected in series;
A wiring part (30) for electrically connecting the monitoring part and the electrode terminals (221, 222) of the battery cell;
A noise removing element (12, 60) provided in at least one of the monitoring unit and the wiring unit,
The wiring portion has a flexible substrate (40) having flexibility, and a wiring pattern (50) formed on the flexible substrate,
The wiring pattern has a connection pattern (51) for connecting the battery cell and the monitoring unit, and a solid pattern (52) for noise countermeasures,
The flexible substrate has a connection region (44) where a connection pattern is formed, and a solid region (45) where a solid pattern is formed,
The flexible substrate can be bent with respect to at least one of the connection region and the monitoring unit such that at least one of the connection region and the monitoring unit is covered with the solid region.

  According to this, it is not necessary to prepare a shield member separately. Therefore, an increase in the number of parts is suppressed.

  In addition, the code | symbol with the parenthesis is attached | subjected to the element as described in the claim as described in a claim, and each means for solving a subject. The reference numerals in parentheses are for simply indicating the correspondence with each component described in the embodiment, and do not necessarily indicate the element itself described in the embodiment. The description of the reference numerals with parentheses does not unnecessarily narrow the scope of the claims.

It is a circuit diagram of a battery pack. It is a top view which shows a battery stack. It is a top view which shows the monitoring apparatus of 1st Embodiment. It is a top view which shows the state with which the monitoring apparatus was provided in the battery stack. It is a top view which shows the state with which the monitoring apparatus was connected with the battery stack. It is sectional drawing which follows the VI-VI line of FIG. It is sectional drawing which follows the VII-VII line of FIG. It is a top view which shows the monitoring apparatus of 2nd Embodiment. It is a top view which shows the state with which the monitoring apparatus was connected with the battery stack. It is a top view which shows the monitoring apparatus of 3rd Embodiment. It is a top view which shows the state with which the monitoring apparatus was connected with the battery stack. It is a top view which shows the monitoring apparatus of 4th Embodiment. It is a top view which shows the state with which the monitoring apparatus was connected with the battery stack. It is a top view which shows the modification of a monitoring apparatus. It is sectional drawing for demonstrating the modification of a solid pattern. It is sectional drawing for demonstrating the separation distance of a solid pattern and a noise removal element. It is a top view which shows the modification of a battery module. FIG. 18 is a top view showing a state where a monitoring device is provided in the battery module shown in FIG. 17. FIG. 18 is a top view showing a state where a monitoring device is connected to the battery module shown in FIG. 17.

  Hereinafter, embodiments will be described with reference to the drawings.

(First embodiment)
The battery pack according to this embodiment will be described with reference to FIGS. The battery pack of this embodiment is applied to a hybrid vehicle. In the following, the three directions that are orthogonal to each other are referred to as a horizontal direction, a vertical direction, and a height direction. In the present embodiment, the lateral direction is along the forward / backward direction of the hybrid vehicle. The vertical direction is along the left-right direction of the hybrid vehicle. The height direction is along the vertical direction of the hybrid vehicle.

(Outline of battery pack)
The battery pack 400 functions to supply power to the electric load of the hybrid vehicle. The electric load includes a motor generator that functions as a power supply source and a power generation source. For example, when the motor generator is powered, the battery pack 400 is discharged to supply power to the motor generator. When the motor generator generates power, the battery pack 400 charges the generated power generated by the power generation.

  The battery pack 400 has a battery ECU 300. The battery ECU 300 is electrically connected to various ECUs (in-vehicle ECUs) mounted on the hybrid vehicle. The battery ECU 300 and the vehicle-mounted ECU mutually transmit and receive signals and cooperatively control the hybrid vehicle.

  The battery pack 400 includes the battery module 200. As shown in FIG. 2, the battery module 200 includes a battery stack 210 in which a plurality of battery cells 220 are electrically and mechanically connected in series.

  The battery pack 400 includes the monitoring device 100. The monitoring device 100 monitors the voltage of each battery cell 220 constituting the battery stack 210.

  As described above, the battery pack 400 includes the monitoring device 100, the battery module 200, and the battery ECU 300. In addition, the battery pack 400 may include a blower fan that cools the battery module 200. The driving of the blower fan is controlled by the battery ECU 300.

  The battery pack 400 is provided, for example, in an arrangement space under the seat of the hybrid vehicle. This arrangement space is wider under the rear seat than under the front seat. The battery pack 400 of this embodiment is provided in the arrangement space under the rear seat. Hereinafter, the battery module 200 and the monitoring device 100 will be described.

(Outline of battery module)
As shown in FIG. 2, the battery module 200 has a battery stack 210. Although not shown, the battery module 200 has a housing for storing the battery stack 210. This housing is formed of aluminum die casting. The housing has a box shape that opens in the height direction and has a bottom. The opening of the housing is covered with a lid. A distribution path through which wind flows is formed inside the housing. A communication hole for communicating the external atmosphere and the communication path is formed in at least one of the housing and the lid.

  The battery stack 210 has a plurality of battery cells 220. The plurality of battery cells 220 are arranged in the vertical direction. The plurality of battery cells 220 are electrically and mechanically connected in series. Therefore, the output voltage of the battery module 200 is a sum of the output voltages of the plurality of battery cells 220.

(Overview of monitoring device)
As shown in FIG. 1, the monitoring device 100 includes a monitoring unit 10 that monitors the voltage of each of the plurality of battery cells 220, and a wiring unit 30 that electrically connects the monitoring unit 10 and each of the plurality of battery cells 220. . Each of the monitoring unit 10 and the wiring unit 30 is provided in the battery module 200. Specifically, the monitoring unit 10 is provided above or on the side of the battery stack 210. The wiring part 30 is provided above the battery stack 210. The wiring unit 30 connects at least one of the positive terminal 221 and the negative terminal 222 of the plurality of battery cells 220 included in the battery stack 210 to the monitoring unit 10.

(Battery stack configuration)
Next, the battery stack 210 will be described in detail with reference to FIG. As described above, the battery stack 210 has a plurality of battery cells 220. The battery cell 220 has a quadrangular prism shape. Therefore, the battery cell 220 has six surfaces.

  The battery cell 220 has an upper end surface 220a facing in the height direction. Although not shown, the battery cell 220 has a lower end surface facing in the height direction. The battery cell 220 has a first side surface 220c and a second side surface 220d facing in the lateral direction. The battery cell 220 has a first main surface 220e and a second main surface 220f facing in the vertical direction. Of these six surfaces, the first main surface 220e and the second main surface 220f have a larger area than the other surfaces.

  The battery cell 220 is a secondary battery. Specifically, the battery cell 220 is a lithium ion battery. A lithium ion battery generates an electromotive voltage by a chemical reaction. A current flows through the battery cell 220 due to generation of the electromotive voltage. Thereby, the battery cell 220 generates heat. The battery cell 220 expands.

  As described above, the first main surface 220e and the second main surface 220f of the battery cell 220 have a larger area than the other surfaces. Therefore, in the battery cell 220, the first main surface 220e and the second main surface 220f are easily expanded. Thereby, the battery cell 220 expands in the vertical direction. That is, the battery cell 220 expands in the direction in which the plurality of battery cells 220 are arranged.

  The battery stack 210 has a restraint (not shown). The plurality of battery cells 220 are mechanically connected in series in the vertical direction by the restraint. Moreover, the increase in the physique of the battery stack 210 due to the expansion of each of the plurality of battery cells 220 is suppressed by the restraint. A gap is formed between adjacent battery cells 220. Heat is radiated from each battery cell 220 by air passing through the gap.

  A positive electrode terminal 221 and a negative electrode terminal 222 are formed on the upper end surface 220 a of the battery cell 220. The positive terminal 221 and the negative terminal 222 are arranged in the horizontal direction. The positive terminal 221 is located on the first side surface 220c side. The negative terminal 222 is located on the second side surface 220d side. The positive terminal 221 and the negative terminal 222 correspond to electrode terminals.

  As shown in FIG. 2, two battery cells 220 arranged adjacent to each other face each other on the first main surfaces 220 e and the second main surfaces 220 f. Thereby, one positive electrode terminal 221 and the other negative electrode terminal 222 of the two battery cells 220 arranged adjacent to each other are arranged in the vertical direction. As a result, in the battery stack 210, the positive terminals 221 and the negative terminals 222 are alternately arranged in the vertical direction.

  In the battery stack 210, a first electrode terminal group 211 in which positive terminals 221 and negative terminals 222 are alternately arranged in the vertical direction, and a second electrode terminal group 212 in which negative terminals 222 and positive terminals 221 are alternately arranged in the vertical direction, , Is configured. In the first electrode terminal group 211 and the second electrode terminal group 212, the arrangement of the positive terminal 221 and the negative terminal 222 is opposite. The first electrode terminal group 211 and the second electrode terminal group 212 are arranged in the horizontal direction.

  Of the electrode terminals constituting the first electrode terminal group 211 and the second electrode terminal group 212, one positive terminal 221 and one negative terminal 222 that are adjacent in the vertical direction extend in the vertical direction. It is electrically connected via. Thereby, the some battery cell 220 which comprises the battery stack 210 is electrically connected in series.

  The battery stack 210 of this embodiment has 16 battery cells 220. These 16 battery cells 220 are connected in series. For this reason, the total number of positive terminals 221 and negative terminals 222 is 32. As shown in FIG. 1 and FIG. 2, these 32 electrode terminals are assigned numbers that increase in number from the lowest potential toward the highest potential. As the number (No) shown in the figure increases, the potential (voltage) of the electrode terminal increases.

  In FIG. The negative electrode terminal 222 of the battery cell 220 described as 0 has a ground potential (lowest potential). No. The positive terminal 221 of the battery cell 220 described as 31 has a potential (maximum potential) obtained by summing the outputs of the battery cells 220. The negative electrode terminal 222 having the lowest potential and the positive electrode terminal 221 having the highest potential are connected to an electric load. As a result, the potential difference between the lowest potential and the highest potential is output to the electric load as the output voltage of the battery module 200.

(Configuration of monitoring device)
Next, the monitoring device 100 will be described in detail with reference to FIGS. As described above, the monitoring device 100 includes the monitoring unit 10 and the wiring unit 30. 3 to 5, the solid pattern 52, the connection pattern 53, and the ground pattern 54 are hatched in order to clarify the configuration.

  As shown in FIG. 1, the monitoring unit 10 includes a printed circuit board 11, a first electronic element 12, and a monitoring IC chip 13. A first electronic element 12 and a monitoring IC chip 13 are mounted on the printed circuit board 11. The first electronic element 12 and the monitoring IC chip 13 are electrically connected via the board wiring 14 of the printed board 11.

  The wiring unit 30 is connected to the printed circuit board 11 of the monitoring unit 10. Thereby, the battery stack 210 and the monitoring unit 10 are electrically connected via the wiring unit 30. The printed circuit board 11 of the monitoring unit 10 is provided with a connector (not shown). A wire 301 is connected to this connector. This wire 301 is connected to battery ECU 300. As a result, the monitoring unit 10 is connected to the battery ECU 300.

  As shown in FIG. 3, the wiring unit 30 includes a flexible substrate 40 having flexibility, a wiring pattern 50 formed on the flexible substrate 40, and a second electronic element 60 formed on the wiring pattern 50. As shown in FIG. 6, each of the wiring pattern 50 and the second electronic element 60 is formed on the surface 40 a of the flexible substrate 40. Each of the front surface 40 a and the back surface 40 b of the flexible substrate 40 is covered with a coating resin 70. The coating resin 70 covers at least a part of the second electronic element 60 and the wiring pattern 50. The flexible substrate 40 corresponds to a flexible substrate. In FIG. 6, a formation position of a second cut 40d described later is schematically shown by a broken line.

  The flexible board 40 is made of a material that is more flexible than the printed board 11. The flexible board 40 is thinner than the printed board 11. Therefore, the flexible substrate 40 can be bent. That is, the flexible substrate 40 can be elastically deformed.

  The flexible substrate 40 has a rectangular shape extending in the vertical direction. The monitoring unit 10 is connected to one end of the flexible substrate 40 in the vertical direction. As shown in FIG. 4, the flexible substrate 40 is provided between the first electrode terminal group 211 and the second electrode terminal group 212 of the battery stack 210.

  A first cut 40 c is formed in the flexible substrate 40. 3 and 4, the first cut 40c is indicated by a one-dot chain line. The first cut 40c penetrates the front surface 40a and the back surface 40b of the flexible substrate 40. The first cut 40c is formed without interruption in the center of the flexible substrate 40 from the one end side to the other end along the vertical direction. Moreover, the 1st cut | interruption 40c is formed without interruption along the horizontal direction in the one end side. Thus, the first cut 40c forms a T shape. The flexible substrate 40 is partitioned into a first electrode terminal group 211 side and a second electrode terminal group 212 side by the first cut 40c.

  The first cut 40 c cuts the other end of the flexible substrate 40. However, the first cut 40c does not open one end of the flexible substrate 40. Therefore, the part on the first electrode terminal group 211 side and the part on the second electrode terminal group 212 side of the flexible substrate 40 are mechanically connected via a part on one end side.

  In the following, in order to simplify the notation, a portion on the first electrode terminal group 211 side in the flexible substrate 40 is referred to as a first FPC 41. A portion on the second electrode terminal group 212 side in the flexible substrate 40 is referred to as a second FPC 42. A portion on one end side of the flexible substrate 40 is referred to as a third FPC 43.

  The third FPC 43 is located between the first FPC 41 and the second FPC 42 in the lateral direction. 3 to 5, in order to clarify the boundary between the third FPC 43 and the first FPC 41 and the boundary between the third FPC 43 and the second FPC 42, each boundary is indicated by a two-dot chain line.

  Each of the first FPC 41 and the second FPC 42 includes a connection region 44 where a connection pattern 51 described later is formed, and a solid region 45 where a solid pattern 52 is formed. As shown in FIG. 4, in a state where the monitoring device 100 is simply provided in the battery stack 210, the connection region 44 of the first FPC 41 is located on the first electrode terminal group 211 side. The solid region 45 of the first FPC 41 is located on the center side of the battery stack 210. On the other hand, the connection region 44 of the second FPC 42 is located on the second electrode terminal group 212 side. The solid region 45 of the second FPC 42 is located on the center side of the battery stack 210. The solid region 45 of the first FPC 41 and the solid region 45 of the second FPC 42 are divided by the first cut 40c. Further, the solid region 45 of the first FPC 41 and the third FPC 43 are divided by the first cut 40c. The solid region 45 of the second FPC 42 and the third FPC 43 are divided by the first cut 40c.

  However, the connection area 44 of the first FPC 41 and the connection area 44 of the second FPC 42 are mechanically coupled via the third FPC 43. A connection pattern 53 (to be described later) is formed on the third FPC 43 side of the connection region 44 of each of the first FPC 41 and the second FPC 42 and on each of the third FPC 43. A ground pattern 54 described later is also formed on the third FPC 43.

  A second cut 40d (perforation) for facilitating the bending of each of the first FPC 41 and the second FPC 42 is formed at the boundary between the connection region 44 and the solid region 45 in each of the first FPC 41 and the second FPC 42. 3 and 4, the second cut 40d is indicated by a broken line. The second cut 40 d is formed along the vertical direction at the boundary between the connection region 44 and the solid region 45. The second cut 40d is formed by a plurality of intermittent notches penetrating the front surface 40a and the back surface 40b of the flexible substrate 40. For this reason, the connection area | region 44 and the solid area | region 45 are mechanically connected through the site | part between the some notches which the 2nd cut | interruption 40d has. Note that the second cut 40d may be formed by alternately arranging locally thin portions and thick portions.

  As shown in FIGS. 5 and 7, the first FPC 41 and the second FPC 42 are curved with the second cut 40 d as the center. The surface 40a of the connection region 44 and the surface 40a of the solid region 45 are opposed to each other in the height direction. By doing so, the solid region 45 and the connection region 44 are arranged to face each other. As shown in FIG. 7, the facing arrangement is set such that the separation distance L <b> 2 between the solid pattern 52 and the second electronic element 60 is longer than the thickness L <b> 1 of the flexible substrate 40. The separation distance L2 is set so that capacitive coupling between the solid pattern 52 and the second electronic element 60 is avoided. As clearly shown in FIG. 7, the separation distance between the solid pattern 52 in the solid area 45 and the connection pattern 51 in the connection area 44 is longer than the separation distance L2. In FIG. 7, the formation position of the second cut 40d is schematically shown by a broken line.

  The wiring pattern 50 includes a connection pattern 51 that electrically connects the monitoring unit 10 and the electrode terminals of the battery cell 220, and a solid pattern 52 for noise suppression that suppresses input of noise to the electronic element. The wiring pattern 50 includes a connection pattern 53 that connects the plurality of solid patterns 52 and a ground pattern 54 that connects the solid patterns 52 to the monitoring unit 10.

  As shown in FIGS. 1 and 4, one end of the connection pattern 51 is connected to the electrode terminal, and the other end is connected to the monitoring unit 10. The wiring pattern 50 has 17 connection patterns 51. A connection terminal 51 a is connected to the end on one end side of each of these 17 connection patterns 51. The second electronic element 60 is provided on the center side or the end side of each connection pattern 51.

  Eight of the 17 connection patterns 51 are formed in the connection region 44 of the first FPC 41. These eight connection patterns 51 are No. 1, No. 1 5, no. 9, no. 13, No17, No.1. 21, no. 25, no. This corresponds to 29 positive terminals 221. Eight connection terminals 51a are provided on the side of the connection region 44 of the first FPC 41 along the vertical direction on the first electrode terminal group 211 side.

  The remaining nine connection patterns 51 are formed in the connection region 44 of the second FPC 42. These nine connection patterns 51 are No. 0 negative terminal 222, No. 2 3, No. 7, no. 11, no. 15, No19, No.1. 23, no. 27, no. This corresponds to 31 positive terminals 221. Nine connection terminals 51a are provided on the side of the connection region 44 of the second FPC 42 along the vertical direction on the second electrode terminal group 212 side.

  As shown in FIG. The negative electrode terminal 222 of 0 and all the positive electrode terminals 221 are electrically connected. Thereby, the wiring part 30 and the battery stack 210 have the electrical connection configuration shown in FIG. These 17 connection terminals 51a are No. 31 positive terminals 221 and all the negative terminals 222 may be electrically connected. Furthermore, the 17 connection terminals 51a are connected to the No. 1 connector. 0 negative terminal 222, No. 2 31 positive terminals 221 and all series terminals 223 may be electrically connected. Any connection configuration is the electrical connection configuration shown in FIG.

  As shown in FIGS. 3 and 4, a solid pattern 52 is formed in each of the solid regions 45 of the first FPC 41 and the second FPC 42. The solid pattern 52 is formed over the entire surface 40 a of the solid region 45. However, a connection terminal 80 for connecting the solid region 45 to the battery stack 210 is connected to the surface 40 a of the solid region 45. A solid pattern 52 is formed on the surface 40 a of the solid region 45 in a manner that avoids a connection portion with the connection terminal 80 on the surface 40 a of the solid region 45. Thereby, the connection terminal 80 and the solid pattern 52 are not electrically connected. The connection surface of the connection terminal 80 and the formation surface of the solid pattern 52 do not have to be the same. For example, the connection terminal 80 may be connected to the front surface 40a, and the solid pattern 52 may be formed on the back surface 40b. However, in order to avoid capacitive coupling between the connection terminal 80 and the solid pattern 52, the connection terminal 80 and the solid pattern 52 are preferably not opposed to each other.

  Four connection terminals 80 are connected to the solid region 45. Two of the four connecting terminals 80 are connected to the solid region 45 of the first FPC 41. These two connection terminals 80 are connected to the first cut 40 c side in the solid region 45 of the first FPC 41. These two connecting terminals 80 are No. 10, no. 26 corresponding to the 26 negative terminals 222.

  The remaining two connecting terminals 80 are connected to the solid region 45 of the second FPC 42. These two connection terminals 80 are connected to the first cut 40 c side in the solid region 45 of the second FPC 42. These two connecting terminals 80 are No. 4, no. This corresponds to 20 negative terminals 222.

  As shown in FIG. 4, the monitoring device 100 is mounted on the battery stack 210 such that the back surface 40 b of the flexible substrate 40 faces the upper end surface 220 a of the battery cell 220. Thereafter, as shown in FIG. 5, the first FPC 41 is curved so that the surface 40 a of the connection region 44 and the surface 40 a of the solid region 45 are opposed to each other in the height direction around the second cut 40 d of the first FPC 41. In this state, the two connecting terminals 80 connected to the solid region 45 of the first FPC 41 are designated as No. 2. 10, no. 26 is fixed to the negative electrode terminal 222 by welding or the like. Thereby, the curved state of the flexible substrate 40 is maintained. As a result, the solid area 45 and the connection area 44 of the first FPC 41 are arranged to face each other. The connection area 44 is covered by the solid area 45.

  Similarly, the second FPC 42 is bent so that the surface 40a of the connection region 44 and the surface 40a of the solid region 45 face each other in the height direction around the second cut 40d of the second FPC 42. In this state, the two connecting terminals 80 connected to the solid region 45 of the second FPC 42 are designated as No. 2. 5, no. 21 is fixed to the negative electrode terminal 222 by welding or the like. Thus, the solid region 45 and the connection region 44 of the second FPC 42 are disposed to face each other. The connection area 44 is covered by the solid area 45.

  As shown in FIGS. 3 and 4, connection patterns 53 are formed in the connection regions 44 and the third FPCs 43 of the first FPC 41 and the second FPC 42, respectively. The connection pattern 53 formed on the first FPC 41 extends from the solid pattern 52 of the first FPC 41 to the third FPC 43 via the second cut 40 d of the first FPC 41. Similarly, the connection pattern 53 formed on the second FPC 42 extends from the solid pattern 52 of the second FPC 42 to the third FPC 43 via the second cut 40 d of the second FPC 42. The connection pattern 53 formed on the third FPC 43 connects the connection pattern 53 of the first FPC 41 and the connection pattern 53 of the second FPC 42. As described above, the solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 are electrically connected via the connection pattern 53.

  In addition, the length (width) of the vertical direction of the site | part formed in the 2nd cut 40d in the connection pattern 53 is longer than the vertical length of the intermittent notch which comprises the 2nd cut 40d. Therefore, the connection pattern 53 is formed at a portion between the plurality of cutouts of the second cut 40d. The vertical direction corresponds to the formation direction.

  A ground pattern 54 is formed on the third FPC 43. One end of the ground pattern 54 is electrically connected to the connection pattern 53, and the other end is electrically connected to the monitoring unit 10. As described above, the solid patterns 52 of the first FPC 41 and the second FPC 42 are electrically connected to the monitoring unit 10 via the connection pattern 53 and the ground pattern 54. As the name suggests, the ground pattern 54 is connected to the ground potential in the monitoring unit 10. As a result, the solid patterns 52 of the first FPC 41 and the second FPC 42 are at the ground potential.

  As described above, the connection region 44 is covered with the solid region 45. Thereby, each of the connection pattern 51 and the second electronic element 60 formed in the connection region 44 is shielded by the solid pattern 52. In FIG. 1, in order to show that each of the connection pattern 51 and the second electronic element 60 is shielded by the solid pattern 52, the connection pattern 51 and the second electronic element 60 are surrounded by a solid pattern 52 indicated by a broken line. Yes.

  The second electronic element 60 includes a fuse 61 and an inductor 62 as shown in FIG. The monitoring unit 10 includes a zener diode 15, a parallel capacitor 16, and a resistor 17 as the first electronic element 12. The second electronic element 60 and the first electronic element 12 correspond to a noise removing element.

  In the following, in order to simplify the description, a wiring constituted by the connection pattern 51 and the substrate wiring 14 that connect the adjacent battery cells 220 connected in series is referred to as a voltage detection wiring. The same number of voltage detection wirings as electrode terminals are formed.

  Each voltage detection line is provided with a fuse 61, an inductor 62, and a resistor 17. From the battery cell 220 toward the monitoring IC chip 13, the fuse 61, the inductor 62, and the resistor 17 are connected in series in this order.

  Each of the Zener diode 15 and the parallel capacitor 16 is connected in parallel between two adjacent voltage detection lines. Specifically, the Zener diode 15 and the parallel capacitor 16 are connected between the inductor 62 and the resistor 17 in the voltage detection line. The anode electrode of the Zener diode 15 is connected to the low potential side. The cathode electrode of the Zener diode 15 is connected to the high potential side. Zener diode 15 and parallel capacitor 16 are mounted on printed circuit board 11.

  The Zener diode 15 has a structure that causes a short-circuit failure (short-circuit failure) when an overvoltage is applied from the battery module 200. Specifically, the Zener diode 15 has a structure in which a PN junction type IC chip is directly held between a pair of leads. Thus, unlike the configuration in which the IC chip and the lead are connected via a wire, the wire is broken by the application of an overvoltage, thereby preventing the Zener diode 15 from being open-failed.

  The fuse 61 is configured to be broken by a large current flowing through the voltage detection wiring when the Zener diode 15 is short-circuited due to overvoltage. The rated current of the fuse 61 is set based on a large current flowing in the voltage detection wiring when the Zener diode 15 is short-circuited due to overvoltage.

  The RC circuit is configured by the resistor 17 and the parallel capacitor 16. The RC circuit and the inductor 62 function as a filter that removes noise during voltage detection. Further, the resistor 17 constituting the RC circuit functions as a current limiting resistor in the equalization process described later.

  Although not shown, the monitoring IC chip 13 includes a microcomputer and a switch corresponding to each of the plurality of battery cells 220. This switch controls the connection between the two voltage detection lines. Therefore, charging / discharging of the battery cell 220 electrically connected to the corresponding voltage detection line is controlled by the opening / closing control of the switch.

  The performance and characteristics of each battery cell 220 differ from each other due to product variations. Therefore, when charging / discharging is repeated, the state of charge (SOC) of each battery cell 220 is different. SOC is an abbreviation for state of charge. This SOC has a correlation with the electromotive voltage of the battery cell 220.

  The battery cell 220 must suppress the occurrence of overdischarge and overcharge due to its nature. In other words, overdischarge and overcharge are an extreme decrease and an increase in SOC. The fact that the SOC of each battery cell 220 varies means that the degree of overdischarge and overcharge of each battery cell 220 also varies. Therefore, in order to accurately control the SOC of the battery stack 210 so as not to be overdischarged and overcharged, it is necessary to equalize the SOC of the plurality of battery cells 220 constituting the battery stack 210. In other words, it is necessary to match the SOC of each of the plurality of battery cells 220 with the SOC of the battery stack 210, which is the average of these.

  Because of such a request, the microcomputer of the monitoring IC chip 13 detects and monitors the output voltage (electromotive voltage) of each of the plurality of battery cells 220. This output voltage is input to battery ECU 300.

  Battery ECU 300 stores a correlation between SOC and electromotive voltage. Battery ECU 300 detects the SOC of each of the plurality of battery cells 220 based on the input output voltage (electromotive voltage) and the stored correlation. The battery ECU 300 determines the SOC equalization process of the plurality of battery cells 220 based on the detected SOC. Then, the battery ECU 300 outputs an instruction for equalization processing based on the determination to the microcomputer of the monitoring IC chip 13. The microcomputer controls opening and closing of the switches corresponding to each of the plurality of battery cells 220 based on an instruction for equalization processing. Thereby, equalization processing is performed.

  Battery ECU 300 also detects the state of charge of battery stack 210 based on the input voltage and the like. The battery ECU 300 outputs the detected charging state of the battery stack 210 to the in-vehicle ECU. The in-vehicle ECU outputs a command signal to the battery ECU 300 based on the state of charge, vehicle information such as an accelerator pedal depression amount and throttle valve opening input from various sensors mounted on the vehicle, and an ignition switch. The battery ECU 300 controls the connection between the battery pack 400 and the electric load based on the command signal.

  Although not shown, a system main relay is provided between the battery stack 210 and the battery pack 400. This system main relay controls the electrical connection between the battery stack 210 and the battery pack 400 by the generation of a magnetic field. The battery ECU 300 controls the connection between the battery pack 400 and the electric load by controlling the generation of the magnetic field of the system main relay.

  The magnetic field generated by this system main relay tries to pass through the monitoring device 100. However, the solid pattern 52 prevents the magnetic field from being input to the connection pattern 51 and the second electronic element 60.

(Function and effect)
Next, the effect of the monitoring apparatus 100 of the battery pack 400 will be described. As described above, when the flexible substrate 40 is curved, the surface 40a of the connection region 44 and the surface 40a of the solid region 45 are opposed to each other in the height direction. Thereby, each of the connection pattern 51 and the second electronic element 60 formed in the connection region 44 is shielded by the solid pattern 52 formed in the solid region 45. For this reason, it is not necessary to prepare a shield member separately. An increase in the number of parts is suppressed.

  The flexible substrate 40 is thin in order to ensure flexibility. Therefore, for example, when the solid pattern 52 is formed on the back surface 40b of the flexible substrate 40, there is a possibility that the solid pattern 52 and the second electronic element 60 and the solid pattern 52 and the connection pattern 51 may be capacitively coupled. However, as described above, the separation distance L2 between the solid pattern 52 and the second electronic element 60 is longer than the thickness L1 of the flexible substrate 40. Thereby, capacitive coupling with the solid pattern 52 is suppressed. Of course, the solid pattern 52 may be formed on the back surface 40b of the flexible substrate 40 when the flexible substrate 40 has a thickness that does not cause capacitive coupling while ensuring flexibility.

  A second cut 40d for facilitating the bending of each of the first FPC 41 and the second FPC 42 is formed at the boundary between the connection region 44 and the solid region 45 in each of the first FPC 41 and the second FPC 42. This facilitates the bending of the flexible substrate 40.

  The solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 are electrically connected via a connection pattern 53. The connection pattern 53 is connected to the ground potential of the monitoring unit 10 through the ground pattern 54. Thereby, each of the plurality of solid patterns 52 can be set to the ground potential.

  The vertical width of the portion formed in the second cut 40d in the connection pattern 53 is longer than the vertical length of the intermittent notches constituting the second cut 40d. According to this, the connection pattern 53 is always formed at a portion between the plurality of notches of the second cut 40d. For this reason, it is suppressed that the electrical connection failure of the connection pattern 53 and the solid pattern 52 arises by the 2nd cut | interruption 40d.

  The flexible substrate 40 is partitioned into a first electrode terminal group 211 side (first FPC 41) and a second electrode terminal group 212 side (second FPC 42) by a first cut 40c. However, the first FPC 41 and the second FPC 42 are mechanically connected via the third FPC 43. According to this, compared with the configuration in which the first FPC 41 and the second FPC 42 are separated, the connection of the monitoring device 100 to the battery stack 210 is suppressed.

(Second Embodiment)
Next, 2nd Embodiment is described based on FIG. 8 and FIG. The monitoring apparatus of each embodiment shown below has much in common with the above-described embodiment. Therefore, in the following description, description of common parts is omitted, and different parts are mainly described. In the following description, the same reference numerals are given to the same elements as those described in the above embodiment.

  In the first embodiment, an example in which the solid patterns 52 of the first FPC 41 and the second FPC 42 are connected to the monitoring unit 10 via the connection pattern 53 and the ground pattern 54 has been described. On the other hand, in the present embodiment, the solid patterns 52 of the first FPC 41 and the second FPC 42 are connected to the battery stack 210 via the connection pattern 53 and the relay pattern 55.

  As shown in FIG. 8 and FIG. A connection pattern 51 corresponding to the zero negative terminal 222 is formed. That is, the connection pattern 51 corresponding to the negative electrode terminal 222 of the ground potential is formed in the connection region 44 of the second FPC 42. In other words, the connection pattern 51 corresponding to the ground potential is formed in the connection region 44 of the second FPC 42.

  In the present embodiment, a relay pattern 55 that electrically connects the connection pattern 51 corresponding to the ground potential and the solid pattern 52 is formed in the second FPC 42. As shown in FIG. 8, the relay pattern 55 is formed in the connection area 44 and the solid area 45 of the second FPC 42. The relay pattern 55 extends from the solid pattern 52 to the connection pattern 51 corresponding to the ground potential via the second cut 40d of the second FPC. Also in this embodiment, the solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 are electrically connected via the connection pattern 53.

  With the above electrical connection configuration, each of the plurality of solid patterns 52 can be set to the ground potential. In addition, an increase in the number of connection terminals of the monitoring unit 10 is suppressed.

  The longitudinal length (width) of the portion formed in the second cut 40d in the relay pattern 55 is longer than the vertical length of the intermittent notches constituting the second cut 40d. According to this, the relay pattern 55 is always formed at a portion between the plurality of cutouts of the second cut 40d. For this reason, it is suppressed that the electrical connection failure of the connection pattern 51 and the solid pattern 52 arises by the 2nd cut | interruption 40d.

  The monitoring device 100 according to the present embodiment includes components equivalent to the monitoring device 100 described in the first embodiment. Therefore, it cannot be overemphasized that there exists an equivalent effect.

(Third embodiment)
Next, 3rd Embodiment is described based on FIG. 10 and FIG. In the first embodiment, no. 4, no. The example in which the connecting terminal 80 corresponding to the 20 negative terminals 222 is connected to the solid region 45 of the second FPC 42 is shown. On the other hand, in the present embodiment, no. 0, No. The connecting terminal 80 corresponding to the 20 negative terminals 222 is connected to the solid region 45 of the second FPC 42. And No. The connection terminal 80 corresponding to the zero negative terminal 222 is electrically connected to the solid pattern 52 of the second FPC 42. This connecting terminal 80 is No. It is mechanically and electrically connected to zero negative terminal 222. Also in the present embodiment, the solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 are electrically connected via the connection pattern 53.

  With the above electrical connection configuration, each of the plurality of solid patterns 52 can be set to the ground potential in the same manner as in the second embodiment. In addition, an increase in the number of connection terminals of the monitoring unit 10 is suppressed.

  It goes without saying that the monitoring apparatus 100 according to the present embodiment also has the same operational effects as the monitoring apparatus 100 described in the first embodiment.

(Fourth embodiment)
Next, 4th Embodiment is described based on FIG. 12 and FIG. In the first embodiment, the connection region 44 is covered with the solid region 45, so that the connection pattern 51 and the second electronic element 60 are shielded by the solid pattern 52. On the other hand, in the present embodiment, the monitoring unit 10 is covered with the solid region 45, so that the monitoring IC chip 13, the first electronic element 12, and the substrate wiring 14 are shielded by the solid pattern 52.

  In the first embodiment, an example in which each of the first FPC 41 and the second FPC 42 includes the connection region 44 and the solid region 45 is shown. In contrast, in the present embodiment, each of the first FPC 41 and the second FPC 42 has a connection area 44, and the third FPC 43 has a solid area 45.

  A solid region 45 is located on the opposite side of the third FPC 43 from the connection end with the monitoring unit 10. The solid region 45 is partitioned by a first cut 40c formed in the vertical direction indicated by a one-dot chain line in FIG. 12 and a second cut 40d formed in the horizontal direction indicated by a broken line in FIG. The solid region 45 is divided into the first FPC 41 and the second FPC 42 by the first cut 40c.

  As shown in FIG. 13, the third FPC 43 is curved so that the surface of the monitoring unit 10 and the surface 40 a of the solid region 45 face each other in the height direction around the second cut 40 d of the third FPC 43. In this state, the third FPC 43 is fixed to the printed circuit board 11 of the monitoring unit 10 by an adhesive or welding. At this time, the solid pattern 52 is connected to the ground potential of the monitoring unit 10. Thus, the solid region 45 and the monitoring unit 10 are disposed to face each other, and the monitoring unit 10 is shielded by the solid pattern 52. In the present embodiment, the layout of the substrate wiring 14 is determined so that the substrate wiring 14 provided with the first electronic element 12 is positioned between the second cut 40d and the monitoring IC chip 13. Therefore, the monitoring IC chip 13, the first electronic element 12, and the substrate wiring 14 are shielded by the solid pattern 52 due to the curvature of the third FPC 43.

  It goes without saying that the monitoring apparatus 100 according to this embodiment also has the same operational effects as the monitoring apparatus 100 described in the first embodiment.

  The preferred embodiments of the present disclosure have been described above. However, the present disclosure is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present disclosure. It is.

(First modification)
In the first embodiment, the second embodiment, and the third embodiment, the solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 are electrically connected via the connection pattern 53. However, the solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 may not be electrically connected. For example, by adopting the configuration shown in FIG. 14, the solid pattern 52 of the first FPC 41 and the solid pattern 52 of the second FPC 42 can be set to the ground potential.

  In the modification shown in FIG. 14, a ground pattern 54 is formed in the connection region 44 of the first FPC 41. The ground pattern 54 electrically connects the solid pattern 52 of the first FPC 41 and the monitoring unit 10. A relay pattern 55 is formed in the connection area 44 of the second FPC 42. The relay pattern 55 electrically connects the connection pattern 51 corresponding to the ground potential and the solid pattern 52 of the second FPC 42 as in the second embodiment. Thereby, the solid patterns 52 of the first FPC 41 and the second FPC 42 can be set to the ground potential.

  Note that the vertical width of the portion formed in the second cut 40d in the ground pattern 54 is longer than the vertical length of the intermittent notches constituting the second cut 40d. According to this, the ground pattern 54 is always formed at a portion between the plurality of cutouts of the second cut 40d. For this reason, the electrical connection failure between the ground pattern 54 and the solid pattern 52 due to the second cut 40d is suppressed.

(Second modification)
In the first embodiment, an example in which each of the connection pattern 51 and the solid pattern 52 is formed on the surface 40a of the flexible substrate 40 as shown in FIG. However, for example, as shown in FIG. 15, a configuration in which the connection pattern 51 is formed on the front surface 40 a of the flexible substrate 40 and the solid pattern 52 is formed on the back surface 40 b of the flexible substrate 40 can be adopted.

  According to this, as shown in FIG. 16, the separation distance L3 between the solid pattern 52 and the second electronic element 60 can always be longer than the thickness L1 of the flexible substrate 40. Thereby, the capacitive coupling between the second electronic element 60 and the solid pattern 52 is suppressed. As clearly shown in FIG. 16, the separation distance between the solid pattern 52 in the solid area 45 and the connection pattern 51 in the connection area 44 is longer than the separation distance L3.

(Third Modification)
In the present embodiment, an example in which the battery module 200 includes one battery stack 210 has been described. However, the battery module 200 may have a plurality of battery stacks 210. In this case, a housing space corresponding to each battery stack 210 is formed in the casing of the battery module 200. The plurality of storage spaces are provided side by side in the horizontal direction.

  For example, the form in which the battery cells 220 of the two battery stacks 210 are connected in series is shown in FIGS. The two battery stacks 210 shown in FIG. 17 have the same number of even-numbered battery cells 220. A negative electrode terminal 222 of the battery cell 220 located on one end side of the two battery stacks 210 and a positive electrode terminal 221 of the battery cell 220 located on the other end side of the two battery stacks 210 are horizontally arranged. They are electrically connected via a series terminal 224 extending in the direction. As a result, the positive terminal 221 of the battery cell 220 located on the other end side of one of the two battery stacks 210 has the highest potential, and the negative terminal 222 of the battery cell 220 located on the other end side of the other battery stack 210 has the lowest potential. The positive electrode terminal 221 having the highest potential and the negative electrode terminal 222 having the lowest potential are arranged side by side. In FIG. 17, the positive electrode terminal 221 having the highest potential and the negative electrode terminal 222 having the lowest potential are indicated by broken lines.

  Also in such a form, the solid pattern 52 of each monitoring device 100 is connected to the ground potential by using, for example, the monitoring device 100 described in the first embodiment for each battery stack 210 as shown in FIGS. can do. Note that the two battery stacks 210 may be electrically connected not by the series terminal 224 but by a wire or the like.

(Other variations)
In each embodiment, the example which applied the battery pack 400 to the hybrid vehicle was shown. However, the battery pack 400 can be applied to, for example, a plug-in hybrid vehicle or an electric vehicle.

  In each embodiment, the example which shields one of the connection area | region 44 and the monitoring part 10 with the solid pattern 52 was shown. Although not shown, both the connection region 44 and the monitoring unit 10 may be shielded by the solid pattern 52. Thereby, each of the connection pattern 51, the second electronic element 60, the monitoring IC chip 13, the first electronic element 12, and the substrate wiring 14 may be shielded by the solid pattern 52.

  In each embodiment, the example in which the first FPC 41 and the second FPC 42 are mechanically connected via the third FPC 43 is shown. However, the first FPC 41, the second FPC 42, and the third FPC 43 do not have to be mechanically connected as long as the electrical connection of the ground potential of the solid pattern 52 is ensured. The third FPC 43 may not be provided as long as at least one of the connection region 44 and the monitoring unit 10 can be shielded by the solid pattern 52.

  In each embodiment, the example in which the connection terminal 80 is mechanically connected to the battery cell 220 by directly connecting the connection terminal 80 to the electrode terminal of the battery cell 220 has been described. However, the connection terminal 80 can also employ a configuration in which the connection terminal 80 is indirectly connected to the battery cell 220 by being connected to the restraining tool or the casing described in the first embodiment and the connection terminal 51a.

DESCRIPTION OF SYMBOLS 10 ... Monitoring part, 12 ... Electronic element, 30 ... Wiring part, 40 ... Flexible board, 40a ... Front surface, 40b ... Back surface, 40c ... First cut, 40d ... Second cut, 41 ... First FPC, 42 ... Second FPC, 43 ... 3rd FPC, 44 ... Connection area, 45 ... Solid area, 50 ... Wiring pattern, 51 ... Connection pattern, 52 ... Solid pattern, 53 ... Connection pattern, 54 ... Ground pattern, 55 ... Relay pattern, 60 ... Electronic element, 80 ... Connection terminal 210 ... Battery stack 211 ... First electrode terminal group 212 ... Second electrode terminal group 220 ... Battery cell 221 ... Positive electrode terminal 222 ... Negative electrode terminal

Claims (9)

A monitoring unit (10) for monitoring voltages of a plurality of battery cells (220) connected in series;
A wiring part (30) for electrically connecting the monitoring part and the electrode terminals (221, 222) of the battery cell;
A noise removing element (12, 60) provided in at least one of the monitoring unit and the wiring unit,
The wiring portion includes a flexible substrate (40) having flexibility, and a wiring pattern (50) formed on the flexible substrate,
The wiring pattern includes a connection pattern (51) for connecting the battery cell and the monitoring unit, and a solid pattern (52) for noise countermeasures,
The flexible substrate has a connection region (44) where the connection pattern is formed, and a solid region (45) where the solid pattern is formed,
The monitoring device is capable of bending the at least one of the connection region and the monitoring unit such that at least one of the connection region and the monitoring unit is covered with the solid region.   The monitoring apparatus according to claim 1, further comprising a connection terminal (80) that is mechanically connected to the battery cell and holds the bending state of the flexible substrate.   The monitoring device according to claim 2, wherein the connection terminal curves the flexible substrate so that a distance between the noise removing element and the solid pattern is longer than a thickness of the flexible substrate.   The monitoring device according to claim 2, wherein the connection terminal is connected to the solid region.   The monitoring device according to claim 4, wherein the connection terminal also serves as an electrical connection between the solid pattern and the electrode terminal.   The monitoring device according to any one of claims 1 to 5, wherein an intermittent cut (40d) is formed at a boundary between the connection region and the solid region in the flexible substrate. A ground pattern (54) for electrically connecting the monitoring unit and the solid pattern is formed at a boundary between the connection region and the solid region,
The monitoring apparatus according to claim 6, wherein a width of the cut formed in a portion formed at a boundary between the connection region and the solid region in the ground pattern is longer than one of the cuts arranged intermittently. A relay pattern (55) for electrically connecting the connection pattern and the solid pattern is formed at the boundary between the connection region and the solid region,
The width of the cut formation direction of a portion formed at a boundary between the connection region and the solid region in the relay pattern is longer than one of the cuts arranged intermittently. Monitoring device. The wiring pattern has a plurality of the solid patterns,
The monitoring device according to any one of claims 1 to 8, wherein the wiring pattern includes a connection pattern (53) for electrically connecting a plurality of the solid patterns in addition to the connection pattern and the solid pattern.

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