TW201232885A - Battery, battery fabricating method and system - Google Patents

Abstract

A battery, comprising: a plurality of battery cells separated by isolating plates; a plurality of detecting units coupled to said battery cells and operable for detecting a status of said battery cells; and a plurality of interfaces coupled to said detecting units and operable for receiving detecting results indicating said status from said detecting units, wherein said battery cells and said detecting units are enveloped inside said battery after said battery is airproofed.

Description

201232885 VI. Description of the Invention: [Technical Field] The present invention relates to a battery, and a battery, a battery manufacturing method, and a battery system. [Prior Art] Generally, batteries are widely used for power supply of electronic devices. Figure 丨 is a block diagram of a prior art battery. As shown in FIG. ,, the battery 1〇2 includes a plurality of battery cells 104J_1〇4-5 separated by the isolation plates. After the battery 1〇2 is sealed, the positive and negative electrodes of the battery 102 protrude from the outside of the battery 〇2. The state of the electricity and the cell 1〇2 can be detected through the positive electrode and the negative electrode of the battery 102. However, when the user wants to detect the state 2 of the internal battery unit just-M〇4-5/since the battery 102 is sealed, and only the positive and negative poles of the battery 1〇2 protrude outside the battery 102, the user needs to be in the battery 1 Drill holes in the corresponding position of 〇2, let the external check it out and (4) the battery unit. However, this financial law is flawed. First, impurities may invade the inside of the battery 1〇2 through the holes, thereby affecting the performance of the battery 102. Second, the coupling of the detecting unit to the internal battery unit is stable. In this way, the detecting unit cannot be connected to the internal battery unit for the third time. Since the 104-1-104-5 has the electric saki, if the position of the user drill is not accurate enough, the hole in the battery unit can leak the electrolyte, battery. Further damage 201232885 Moreover, mounting the external detection unit on the battery changes the shape or size of the battery. In this case, the electric materials (4) are combined with certain products, or the materials are modified to suit the detection unit. SUMMARY OF THE INVENTION The technical problem to be solved by the present invention is to provide a battery, a battery manufacturing method, and a battery cell. The state of the internal battery unit can be detected without additional drilling on the battery. In order to solve the above technical problem, the present invention provides a battery comprising: a plurality of battery cells 'separated by a plurality of isolation plates; a plurality of detection units, and a plurality of battery cells are secreted, and detecting a plurality of the plurality of battery cells a plurality of interfaces 'and the plurality of detection units _, and receiving a plurality of inspection results from the plurality of detection units and representing the plurality of states, wherein: the plurality of battery cells after the battery is sealed And the plurality of tests are sealed within the battery. The present invention further provides a method for manufacturing a battery, comprising: a plurality of isolation plates separating a plurality of battery cells; and a plurality of detection sheets: in the battery to detect a plurality of states of the plurality of battery cells, The plurality of interface outputs of the detecting unit are derived from the detecting unit and represent the plurality of shapes of the plurality of battery cells and sealing the battery to seal the plurality of battery cells and the _ element Inside the battery. (4) Early 7L is provided by 201232885. The present invention further provides a battery system comprising: a plurality of battery cells separated by a plurality of isolation plates; a plurality of detection units coupled to the plurality of batteries, and detecting the a plurality of states of the plurality of battery cells; and a battery cell unit coupled to the plurality of detection units, and receiving the plurality of state (four) detection results from the plurality of detection units, and according to the The plurality of battery cells 7L, the plurality of detection units, and the battery management unit are Sealed within the battery. Compared with the prior art, the battery of the present invention, the method of manufacturing the battery, and the battery system can detect the shape of the internal battery unit without additional drilling on the battery. So - come, {have the integrity of the battery and protect the battery from impurities. The technical solutions of the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments. [Embodiment] Hereinafter, a detailed description will be given of an embodiment of the present invention. While the invention will be described in conjunction with the embodiments, it is understood that the invention is not limited to the embodiments. The invention is intended to cover various modifications, adaptations and equivalents of the invention and the scope of the invention as defined by the scope of the appended claims.

5 S 201232885—Bu-cho's detailed description of the invention, clarifying a large number of details to provide a comprehensive understanding of this issue (four). However, it will be understood by those skilled in the art that the present invention may be practiced without these specific details. In the examples of the present invention, the methods, the flows, the components and the circuits are not described in detail in order to highlight the gist of the present invention. - In the embodiment - the invention discloses a battery with an embedded test unit. The battery contains a plurality of battery sheets that are smashed by the board and are contending via the power rod. A plurality of detection units and a plurality of battery units are secreted to detect the state of the battery unit 7L. After the battery is sealed, the detection unit is embedded in the battery. The result of the detection unit is output through a plurality of interfaces outside the battery. The advantage is that the user can detect the shape of the internal battery unit without the iron hole of the battery, thus maintaining the integrity of the battery without introducing impurities into the battery. 2A is a block diagram of a battery 202A including an embedded detection unit in accordance with an embodiment of the present invention. Battery 202A contains a plurality of battery cells (not shown in Figure 2A) that are isolated by the isolation plates. After the battery 202A is sealed, a plurality of interfaces (e.g., a plurality of pins of the coupler 2〇8 and the positive electrode 204 and the negative electrode 206 of the battery 2〇2A) are located on the surface of the battery 202A. In a consistent embodiment, coupler 208, positive electrode 204, and negative electrode 206 are located on the top panel of battery 202A. In one embodiment, a plurality of detection units are embedded in the battery 202A, and the status of the internal battery unit is checked at 201232885. The footer 208 (four) is lightly connected to the embedded check unit, and each pin is respectively connected with one test unit. In the battery 202A ^ month 1J, the pin and the embedded detecting unit are disposed inside the battery 202A, and the connected circuit is so - after the battery 2G2A is sealed, the circuit is clamped in the battery 2G2A. In this way, the battery management unit monitors the status of the internal battery unit through the pin' and takes predetermined measures according to the status. For example, if the battery management unit detects an abnormal state of the battery unit, for example, (10) the voltage of the battery unit is "at a predetermined threshold value, the battery management unit takes protective measures. The advantage is that the state of the battery cell in the battery 202A is detected by the embedded detecting unit when the battery 20 is used, and the detection result is output via the coupler 2〇8. As a result, the user does not need to drill the battery 202A to install the external detecting unit. Therefore, there is no need to drill holes in the completion of the battery transfer A, and the impurities are not introduced into the battery 202A. Moreover, since the user does not have to install additional components on the battery 202A, the size and shape of the battery 2A2A need not be changed. Thus, the battery can be used in the prior art application system without changing the application system. Therefore, the designer can design an age-old device that mounts the battery 2G2A to various system towels. Further, the 'coupler 208 further includes (10) which is lightly connected to the positive electrode 2〇4 and the negative electrode 206 of the battery 2〇2A. Before the battery 2〇2A is sealed, a circuit in which the pins are lightly connected to the positive electrode 2〇4 and the negative electrode 2〇6 is disposed inside the battery 2〇2A, as in 201232885, after the battery 202A is sealed, the circuit is embedded in the battery 2〇. 2A. In this way, the battery management unit also monitors the state of the battery 2〇2A through the coupler 2〇8. The advantage is that the circuit for coupling the battery management unit to the positive electrode 2〇4 and the negative electrode 206 is omitted, thereby reducing the cost and reducing the size. In another embodiment, the coupler 208 is located anywhere outside of the battery 202B, as shown in Figure 2B. After the battery 2〇2B is sealed, the cable 21〇 extends from the battery 202B. In the cable 21(), a plurality of wires are arranged side by side, mutually subtracted, wound or braided to form a single device. In the battery surface, the wires of the cable 21 are isolated from each other and connected to the back-in detection single core to transmit information indicating the state of the internal battery unit. Before the battery is moved, the circuit of the wire and the mourning unit in Wei 21〇 is replaced. As such, the circuit is embedded in the battery toilet after the battery 2q2b is sealed. The device is connected to the battery 诵 at the end of the external cable 210. Further, the electric wire in the 21 〇 and the positive electrode 2 〇 4 and the negative electrode of the battery 2 are transferred to transmit information indicating the state of the battery 2 . The -to-coupler 2G8 also receives the data through the corresponding (10) and outputs the data. The advantage is that the position of the reducer 2〇8 is more flexible and there is no need to install the battery 2 (4). Moreover, the shape of the battery pack is simpler, which simplifies the design of the mounting device for mounting the battery 2_ to the application system. 201232885 Fig. 3A shows a block diagram of a battery including an embedded detecting unit, for example, a battery 202A of Fig. 2At or a battery 202B of Fig. 2B, in accordance with an embodiment of the present invention.

In the example of Fig. 3A, the battery 3''' representing the battery 202A of Fig. 2A or the battery 202B of Fig. 2B includes a plurality of battery cells 304_1-304-6 isolated by the isolation plates. Battery 302 can include any number of battery cells. The separator plate 312-1 isolates the battery 3〇2 on one side of the battery 3〇2. The spacer 312_2 isolates the battery unit 3〇4-i and the battery unit 3〇4-2. The electric plates 306_1 and 3G6_2 are used as the positive and negative plates of the battery unit, and are disposed in the battery cells 3〇4j adjacent to the isolation plates 312-1 and 312-1. An electrolyte, such as an acid solution, is injected into the gap between the electric plates 3〇6-1 and 306-2 of the battery unit 3〇4”. Similarly, the positive and negative plates of the battery cells 304-2 - 304 6 are adjacent to the respective separator plates. For example, the negative electrode plate 306-2 of the lead-acid bar 308_ and the positive electrode plate of the battery cell class-2 are further connected in series with the battery cell _-ground, the shore of the 蛱 蛱. Similarly ^〇4:^^,^30〇,3〇4_3,3〇4^ Bamboo battery early 304-- and 304-6 are connected in series. Moreover, the plurality of detecting units and the battery unit 3〇41_3〇4 are used to detect the state of the battery unit, and the state of the battery unit. In the embodiment, the electricity

S 201232885 rod (for example, the metal rod is partially embedded in the electric rod chapter to measure the state of the battery single magic G4J and 3G4_2, for example, the output battery sheet: the negative voltage of 304-i and the positive of the battery unit 3〇4-2 Fig. 3B shows how the test unit is embedded in the battery in accordance with an embodiment of the present invention. In the example of Fig. 3B, the electric housing 308-1' of the electric rod 轻 is lightly connected to the board _2 Between 3G6 and 3. The surface of the shell n, _ has a hole. The diameter of the hole cuts the diameter of the rod 3ig. The rod 31 is inserted into the shell 308J for a period of time. 'Through the hole and the electric rod 31 (U's _ gap injecting liquid metal, for example, liquid is wrong, until the liquid is filled with the electric shell). As a result, when the liquid becomes solid, 'forms the electric rod over-1, the electric rod 31G i is firmly mounted on the electric lever 308 1. ^ Also, referring to Fig. 3A, the electric rods 31〇__2-310_5 are partially embedded in the electric rod, respectively, in the state of the nozzle unit 304-2-3G4-6. Moreover, the electric rods of the positive electrode 204 and the negative electrode 206 are fixed to the positive electrode plate 3G6-1 of the battery unit 304_1 and the battery unit 3G4-6. The negative plate writes -4 to check the positive and negative voltages of the J battery 302. Therefore, the circuit board passes through the electric bars 31 (i in Fig. 3A), 〇~i_31〇_5, the positive electrode 2〇4, and the negative electrode 2〇6. The battery unit 304 1-304 6 ^ - is connected. The circuit of the coupler 208 is connected to the electric poles 310"_31 〇 5 5 on the circuit board. FIG. 4 is not an embodiment according to the present invention. Configuring multiple interfaces, 201232885, for example, a block diagram of the circuit board 400 of the coupler 208 of FIG. 2A and/or FIG. 2B coupled to a plurality of detection units embedded in the battery. FIG. 4 in conjunction with FIG. 2A and FIG. 3A is described. In Fig. 4, elements 4a and 4B show a plan view and a perspective view of circuit board 400. The size and shape of circuit board 400 matches the size and shape of battery 302. The circuit board 4 is matched to the internal battery cells of the battery 3. The positions of the holes 404_1-404_7 on the circuit board 400 are the same as those of the bars 310-1-310_5, the positive electrode 204 and the negative electrode in the battery 302, as shown in plan view 400A. The positions of 206 are matched, and the size of the holes is the same as the size of the electric bars 310_1-310-5, the positive electrode 204, and the negative electrode 206. In this way, when the circuit board 400 is placed on the battery cells 304 1-304 ____ of the battery 302, the 'electric bars 31 〇 1-3 1-10_5, the positive electrode 204 and the negative electrode 206 pass through the corresponding holes 404_1 - 404_7 through the circuit board. 400. Moreover, the position of the holes 406_1-406-6 on the circuit board 400 matches the position of the gap between the positive and negative plates of the battery cells 304-1 - 304-6. Thus, when the circuit board 400 is placed on the battery 302, the holes 406-l-406_6 directly pass through the gap between the positive and negative plates of the battery cells 304-1 - 304_6. After the circuit board 400 is placed on the battery 302, the electrolyte is injected through the holes 406-1-406-6 in the gap between the positive electrode plate and the negative electrode plate of the battery cells 304_1-304_6.

S 11 201232885 As shown in perspective view 400B, the intermediate portion of circuit board 400 in which holes 402-4-406-6 are located is recessed downwardly compared to other areas of circuit board 400. In addition, the passages of the holes 404_1 - 404 - 7 to the intermediate portion are also recessed downward as compared with other regions of the circuit board 4 . Thus, the circuit of the pin of the coupler 2〇8 is coupled to the electric poles 310-1-310-5, the positive electrode 2〇4 and the negative electrode 206 in the channel and the intermediate region. The advantage is that the wires of the circuit no longer protrude from the surface of the circuit board 400. Thus the surface of the circuit board 400 is relatively flat. As a result, the battery 302 is ready to be sealed in subsequent operations. Figure 5 is a block diagram of a battery 500', e.g., battery 3〇2, shown in Figure 3A, after the circuit board is mounted on a battery, in accordance with an embodiment of the present invention. As shown in FIG. 5, after the circuit board 400 is placed on the battery 3〇2, the electric bars 310_1-310_5, the positive electrode 204 and the negative electrode 206 pass through the circuit board 4〇〇, and the other parts of the internal battery cells 304_1-304_6 are borrowed from the circuit board. 4 〇〇 sealed. In addition, the holes 406 - 1-406 - 6 pass directly through the gap between the battery cells. In Fig. 5, the position of the battery unit is indicated by a broken line on the battery 302.

Figure 6A is a block diagram of a circuit 600 person on a circuit board, such as the circuit board 400 shown in Figure 4, in accordance with an embodiment of the present invention. Figure 6A is described in conjunction with Figures 2A' Figures 3A and 4. In the example of FIG. 6A, in an embodiment, the coupler 28 is mounted 12 201232885 on the circuit board 400. When the circuit board 4 is placed on the battery 3〇2, the electric bars 310_1 - 310-5, the positive electrode 204 and the negative electrode 206 pass through the corresponding holes through the circuit board 400. As described above, the electric bar as the detecting unit detects the internal battery unit 3 (^.3 (the state of the ^6, the positive electrode and the negative electrode 2〇6 indicate the positive and negative electrodes of the battery 302. The wires 6〇4A-16〇4a-7 are coupled) Between the detecting unit 3HU-31〇-5, the positive electrode and the negative electrode and the secret device, and located in the channel and the intermediate region of the circuit board 4〇〇 recessed. Therefore, the wires 604A- 1-604A” are arranged side by side in the middle region. And coupled to the coupler 208 via each pin. In operation, the battery management unit corresponds to the coupler 2〇8 coupled to the detecting unit 310-1-310-5, the positive pole 204 and the negative pole 206. The pin monitors the state of the internal battery unit 3〇4-6 and the entire battery 3〇2, for example, the internal battery unit tears the voltage of the entire battery 3〇2. In addition, the circuit board 400 is mounted on the battery 3〇. After 2, the electrolyte is injected through the holes 406-1-406-6 in the gap between the positive electrode and the negative electrode of the battery cell until the electrolyte fills the battery cells 304_1-304_6. Then, the sealing hole 406-1_4〇6_6 is prevented. The electrolyte leaks. The wires 604A--604A_7 are mounted on the circuit board 400 and dense. After a hole on a 6 4061-406, sealed with a battery cover 3〇2 shown in Figure 2A, in addition to the positive electrode seal plate fork 204, other than the negative electrode 206 and the coupling 208 which

S 13 201232885 Other components. Figure 6B shows a circuit block diagram 〇〇B on a circuit board, such as circuit board 400 of Figure 4, in accordance with another embodiment of the present invention. FIG. 6B is described in conjunction with FIGS. 2B, 3B, and 4. In the example of Fig. 6B, when the circuit board 4 is placed on the battery 3〇2, the electric bars 310_1-310-5, the positive electrode 204, and the negative electrode 206 pass through the corresponding holes through the circuit board 400. As described above, the electric bar 31〇5 is used as a detecting unit to detect the state of the internal battery cells 304_1-304_6, and the positive electrode 2〇4 and the negative electrode 206 represent the positive and negative electrodes of the battery 302. The wires 604A_1-604A-7, which are connected between the detecting units 310_1-310_5, the positive electrode 204, and the negative electrode 〇6 and the coupler 208, are located in the recessed channel and intermediate portion of the circuit board 400. Therefore, the 'wires 604A_1-604A_7 are arranged side by side in the middle area and are placed in a soft medium to form a strip structure, such as the cable 21〇〇 after the battery 302 is sealed, including the wires 6〇4A-〗 _6〇4 8_7 Cable 210 extends from battery 202B and is coupled to coupler 208. As shown in Fig. 2B, the corresponding pins of the adapter 208 are transferred via the wires 604A_1-604A_7 in the electrical gauge 21A to the detecting units 3101-310-5, the positive pole 204 and the negative pole 206. Figure 7 is a circuit block diagram of a circuit board 7A in accordance with another embodiment of the present invention. Figure 7 is described in conjunction with Figures 2A, 3A and 4. In the example of FIG. 7, the structure of the circuit board 700 is similar to that of the circuit 201232885 board 400 of FIG. As a result, when the circuit board 7 (8) is mounted on the battery 302, the electric bars 310-1 - 103 - 5, the positive electrode 204 and the negative electrode 206 pass through the corresponding holes through the circuit board 700. In addition, the electrolyte is injected into the battery cells 304 1-304-6 through the corresponding holes 406_1-406_6. However, in comparison with the circuit board 400, the printed circuit board 702 is fixed in the intermediate portion of the circuit board 7A except for the area occupied by the holes 406 1-406-6. The shaded area shown in Fig. 7 represents the printed circuit board 702 of the circuit board 7''. In an embodiment, the coupler 208 is mounted on a printed circuit board 702. Moreover, solder holes 706 1-706 7 are formed (e.g., drilled) on the printed circuit board 702. The welding holes 706-1-706-7 are located near the passages corresponding to the electrolytic bars 310_1-310_5, the positive electrode 204, and the negative electrode 206. On printed circuit board 702, solder vias 706_1-706-7 are lightly coupled to corresponding pins of coupler 208 via a conductive path, trace or signal path etched through a copper sheet laminated on a non-conducting substrate. After the circuit board 700 is mounted on the battery 302, the electric bars 310-1-310_5, the positive electrode 204, and the negative electrode 206 are coupled to the corresponding welding holes 706_1-706_7 through the wires 704_1-704-7 between the pair of electric bars and the holes. As described above, the solder holes 706_1-706-7 are coupled to the corresponding pins of the coupler 208 via conduction paths, tracks or signal paths on the printed circuit board 7〇2. The electric bar 310-1-310-5 detects the state of the internal battery unit 304-1-304-6 as a detecting unit, and the positive electrode 204 and the negative electrode 206 represent the battery 302.

S 15 201232885 Positive and negative. In this way, the detecting unit 31〇_l-31〇_5, the positive electrode 204 and the negative electrode 2〇6 are coupled to the corresponding pins of the coupler 208. After the detecting unit 310__1-31〇_5, the positive electrode 204, and the negative electrode 206 are coupled to the corresponding pins of the coupler 208 via the wires 704-1-4_7, the battery 302 is sealed with a cover. As shown in FIG. 2A, the cover plate seals other components than the positive electrode 204 and the negative electrode 206 of the battery 302 and the coupler 208. In addition, other detecting units, for example, one or more thermistors may be embedded in the battery 302 to detect the shape of the internal battery unit 3〇4-13〇4-6, for example, detecting the battery unit 304-1-3〇 4_6 temperature. The coupler 208 corresponds to (10) and those "type detection unit secrets to receive the output of those detection units. Similarly, before the battery is sealed, the corresponding pins of the detection unit and the wheel connector are arranged in the battery 3〇2. The circuit, so that after the 'money sealed battery welcome, the circuit is also sealed. In the wide range of ways, the battery management unit can also be configured in the printed MH detection unit IWO, the positive and negative 206 and the battery management unit. The company will turn the test results of the state of the internal lightning and ice separation of the battery 3 02 to the second: According to the test result, the state of the test is monitored _ W pf I is early in the state of the root 202A. -6* The entire battery and the state of 201232885 304_1-304_6 take predetermined measures to prevent damage of the internal battery cells 304_1-304_6 and the entire battery 202A. After the battery is sealed, the battery management unit and associated circuits are also sealed in the battery. FIG. 8A is a block diagram of an application system 800A including a battery including an embedded detection unit, such as battery 202A of FIG. 2A or battery 202B of FIG. 2B, in accordance with an embodiment of the present invention. 8A is described in conjunction with Figures 2A and 3A. In application system 800A, battery 202A is coupled to electronic device 802 and provides power to electronic device 802. Moreover, battery management unit 804 is coupled to coupler 208 and monitors the interior. The state of the battery cells 304_1-304_6 and the entire battery 202A, and predetermined measures are taken to prevent the internal battery cells 304_1-304_6 and the entire battery 202A from being damaged. More specifically, the battery management unit 804 is coupled to the coupler 208 via the cable 806. The pins are coupled. As such, the battery management unit 804 monitors the state of the internal battery cells 304_1-304_6 via pins corresponding to the couplers 208 coupled to the embedded detection units 310_1-310_5 in the battery 202A. The battery management unit 804 monitors the voltages of the internal battery cells 304_1-304_6 by calculating the voltage difference between the positive voltage and the negative voltage of the internal battery cells 3 04_1 - 304_6 detected by the detecting units 310_1 - 310_5. If the battery management unit 804 detects The voltage of one of the internal battery cells 304 1-304 6 is greater than a predetermined threshold,

S 17 201232885 Damage The battery management unit 804 has an abnormal condition in that battery unit. In this way, the battery management unit 8G4 takes protective measures to prevent the battery unit. Moreover, the battery management unit 804 also monitors the battery test by the adapter 208 connected to the positive and negative poles. In an embodiment, the battery management unit 8〇4 monitors the voltage of the battery 202A by calculating the voltage difference between the positive and negative voltages of the battery 2G2A at the positive and negative electrodes 206. If the battery management unit 8〇4 detects that the voltage of the battery 202A is greater than the critical value, the battery unit_determination battery 202A has an abnormal condition. In this way, the battery management unit takes protective measures to prevent damage to the battery 2〇2A. In an embodiment, the battery management unit 804 is embedded in the electronic device 8〇2. However, in another embodiment, the battery management unit 804 can also be located external to the electronic device 8G2 and in communication with the electronic device house. In addition, if the consumer 208 is connected to the battery via a cable 210, such as the battery of Figure 2B, the Lighter adapter 2A can be placed anywhere in the Application System_A. The battery management unit 8〇4 is switched via the cable to the lighter 208 of the battery 2〇2B and operates in a similar manner as shown above. In another embodiment, as shown in the application system 8B of FIG. 83, the battery management unit 804 can also be configured and sealed in the battery, for example, the battery 2〇2a or 202B+' Communicates with the external 18 201232885 device 8〇2 via the consumer 2〇8. For example, when a gas is produced, 1Wj, such as the battery buried unit 804 is disposed on the circuit board 400 # / or the circuit board. As described above, the battery management unit (10)* receives the detection results from the state of the internal type of the internal battery unit and the entire battery from the diffused detection unit 31〇_U3l〇5, the positive electrode 2〇4, and the negative electrode, and the result of the detection. Battery bill $ and the status of the entire battery. The battery is transferred to the electronic device by the plurality of pins of the coupler 2〇8 via the plurality of pins of the coupler 2〇8, and the internal battery unit is married to the second device. :: is a flow chart for the battery 2 〇 2α 方法 method in the Fig. 2 制造 according to the invention. The manufacture of battery 2 (four) in ... = face _ medium, in the battery, by a number of isolation plates 7 ° earlier. In the step, each electric board is placed in the vicinity of each of the battery sheets and the positive and negative plates. In step 9〇6, the electric rod (for example, the side of the battery sheet adjacent to the corresponding partition plate, the lead rod) is coupled between each two phases in the vicinity of the adjacent electric board, and is connected in series. In 9〇8, a plurality of states of a plurality of battery cells are picked up. In the case of electricity; also in the case of detecting electric smashing, the electric bar is embedded in the state of each cell = unit: ', for example, detecting electricity on CS: 19 201232885 battery. In the step ,, the detecting unit and the circuit of the plurality of interfaces are mounted on the circuit board, and the plurality of detecting units are lightly connected. In step 914, the holes are passed through the positive plate of the electrical battery cell and the core. In step _, (4) the battery, the components in the p cell except the positive and negative electrodes of the battery and the interface are sealed. Accordingly, the present invention provides a battery containing an embedded unit. The advantage is that the embedded detection unit detects the state of the battery unit and outputs the detection result via the interface. In this way, the state of the internal battery unit can be detected without additional drilling on the battery. Therefore, the integrity of the battery is maintained and the battery is protected from impurities. Moreover, since no additional component filaments are on the wire surface, the size and shape of the battery is similar to that of prior art batteries. Therefore, the battery can be used in an application system of the prior art without changing the application system including the mounting device. The above detailed description and the accompanying drawings are only typical embodiments of the invention. It will be apparent that various additions, modifications and substitutions are possible without departing from the spirit of the invention and the scope of the invention as defined by the appended claims. It should be understood by those skilled in the art that the present invention may be modified in form, structure, arrangement, ratio, material, component, component, and other aspects without departing from the scope of the invention. The scope of the present invention is defined by the scope of the appended claims and their legal equivalents, and is not limited by the foregoing description. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a prior art battery; FIG. 2A is a block diagram of a battery including an embedded detecting unit according to an embodiment of the present invention; A block diagram of a battery including an embedded detecting unit according to another embodiment of the present invention; and FIG. 3A is a block diagram showing an internal structure of a battery including an embedded detecting unit according to an embodiment of the present invention; FIG. 4 is a block diagram of a circuit board according to an embodiment of the present invention; FIG. 5 is a block diagram of a circuit board according to an embodiment of the present invention; FIG. 6A is a block diagram of a circuit board on a battery according to an embodiment of the present invention; FIG. 6A is a block diagram of a circuit board on a circuit board according to an embodiment of the present invention; FIG. 7 is a block diagram of a circuit board on a circuit board according to another embodiment of the present invention; FIG. 8A is a block diagram of a detecting unit, and FIG. 8A is a block diagram of a detecting unit according to an embodiment of the present invention. contain Battery with an embedded application system block diagram; is shown according to another embodiment comprising the present invention contains embedded

A block diagram of an application system for a battery of the type detection unit of S 21 201232885; and FIG. 9 is a flow chart showing a method of manufacturing a battery including an embedded detection unit according to an embodiment of the present invention. [Main component symbol description] 102: Battery 104_1 104104_5: Battery unit 202A to 202B: Battery 204: Positive electrode 206: Negative electrode 208: Coupling device 210: Cable 302: Battery 304_1 to 304_6: Battery unit 306_1 to 306_4: Electric board 308_1 : Electric levers 310_1 to 310_5 : Electric bars 312_1 to 312_2 : Isolation plate 308_1 ' : Electric case 400 : Circuit board 400 8 to 40 (^: Element 4〇4_1 to 404_7: Holes 406-1 to 406_6 • Hole 500: Battery 600A ~600B: Circuit 22 on the board 201232885 604A_1~604A_7: Wire 700: Circuit board 704_1~704_7: Wire 706_1~706_7: Soldering holes 800A~800B: Application system 802: Electronic device 804: Battery management unit 806: Cable 900: Manufacturing method 902 to 916: steps

S 23

Claims (1)

201232885 VII. Patent application scope: ι A battery comprising: a plurality of battery cells separated by a plurality of isolation plates; a plurality of detection units coupled to the plurality of battery cells and detecting a plurality of the plurality of battery cells a plurality of interfaces coupled to the plurality of detection units and receiving a plurality of detection results from the plurality of detection units and representing the plurality of states, wherein 'the plurality of batteries after the battery is sealed The unit and the plurality of detection units are sealed within the battery. 2. The battery of claim 1, further comprising: a circuit board coupled to the plurality of battery cells via the plurality of detecting units to lightly connect the plurality of interfaces and a circuit of the plurality of detecting units Mounted on the circuit board, the circuit board is sealed within the battery after the battery is sealed. 3. The battery of claim 2, wherein the circuit board comprises a hole, after the circuit board is mounted on the plurality of battery cells, an electrolyte is injected through the plurality of holes The plurality of battery cells are sealed after the electrolyte is injected. The battery of claim 1, further comprising: a plurality of positive electrodes and a plurality of negative electrodes connected to the battery, and connecting the plurality of positive electrodes and the plurality of negative electrodes to the battery The plurality of status information, such as the battery of claim 1, further comprising: a plurality of electric bars, each of the plurality of electric rods being connected between the adjacent plurality of battery units, and 6. The battery of claim 5, wherein the detecting unit comprises a plurality of electric sticks embedded in the plurality of electric rods to detect the battery. A plurality of batteries of the plurality of battery cells. The battery of claim 1, wherein the plurality of interfaces comprise a coupler, the coupler comprising a plurality of pins, the plurality of pins The detecting unit is coupled to receive the plurality of detecting results. The battery of claim 1, wherein the detecting unit comprises at least one thermistor to detect the temperature of the plurality of battery cells. Such as applying for the first item of patent scope a pool, wherein a battery management unit receives the plurality of detection results from the plurality of interfaces, and takes a plurality of predetermined measures according to the plurality of detection results. 1. A battery manufacturing method, comprising: the battery Separating a plurality of battery cells by the plurality of isolation plates; dispersing a plurality of detection cells in the battery to detect a plurality of states of the plurality of power cells; and outputting the plurality of interfaces through the plurality of detection units from the *H: =: a plurality of electric cells of the plurality of states of the plurality of battery cells = the plurality of battery cells and the plurality of detecting cells U. As claimed in the first method of the first method, the step comprises: the plurality of detecting units 1 way board installed in this;; battery single S 25 201232885 «•Set a circuit to lightly connect the multiple detection units; and the circuit board more than (4) the battery seals the board at 2· For example, within the method of applying for patent scope item u. When the board is charged in the electrician's contains: multiple holes on the board for the multiple electric &amp; after 'through' and (four) pool early heart master Into the electrolyte; to inject the electricity After the liquid, the plurality of holes are sealed. As in the method of claim </ RTI> </ RTI> </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> </ RTI> </ RTI> </ RTI> multiple states information is transmitted through the plurality of positive electrodes and the plurality of negative ιs of the battery. A plurality of interfaces of _ 14. The method of claim 1, wherein the step-by-step includes: connecting the plurality of battery cells adjacent to the plurality of battery cells. The method of item 14, wherein the plurality of tests are further included in the battery further:: two electric bars are embedded in the electric rod to detect _ adjacent ones of the plurality of batteries A voltage information. The method of claim 10, wherein the detecting the detection further comprises: ??? outputting the plurality of detection results from the plurality of pins of the -coupler. H is 7L::=, the method of item 1, wherein the detecting unit t further comprises: embedding at least one thermistor in the battery to detect the plurality of electricity 26 17 201232885 Multiple temperatures of the pool unit. 18. The battery system 'contains:: one battery unit' is isolated by a plurality of isolation plates; 2% solution, and the plurality of battery cells are secret, and detects the multiple, multiple states of the battery unit; and also the management unit And the plurality of intoxication elements are subtracted, and a plurality of detections are received, and a plurality of detections indicating (four) states are received, and a plurality of predetermined measures are taken according to the plurality of detection results, and the battery is The management unit communicates with the external device via the (four) interface, after the battery is sealed, the plurality of battery cells, the plurality of cells 19 and the battery management unit are sealed within the battery. Patent Application No. 18 The battery system, the step further comprises: - the circuit board is mounted on the plurality of battery cells, and the measuring units are lightly connected, wherein the battery tube is coupled to the battery tube _ = a detecting unit and the battery management unit is lightly connected The interface 1 = = is mounted on the circuit board, and the battery is sealed in the battery after the battery is sealed. The battery system of claim 19, wherein the package has a hole, On the board After being installed in the plurality of battery sheets, an electrolyte is injected into the plurality of dead elements through the plurality of holes, and the plurality of holes are sealed after the electrolyte is injected. The 18-cell battery system includes: the battery is a plurality of electric rods, and each of the plurality of electric rods is lightly connected between the plurality of battery units, so that the plurality of battery units are connected in series The battery system of claim 21, wherein the plurality of detecting units comprise a plurality of electric rods embedded in the electric rod to detect a plurality of voltages of the plurality of battery units. The battery system of claim 18, wherein the detecting unit further comprises at least one thermistor to detect a plurality of temperatures of the plurality of battery cells.