TWI472785B - Intelligent Scheduling System for Battery Test Production and Its - Google Patents

Description

Smart test scheduling system for battery test production and method thereof

The present invention provides a smart scheduling system, and more particularly to a smart scheduling system and method for battery test production that reduces production costs and saves electricity.

According to the advancement of technology, batteries are an indispensable source of energy for many electronic products. As is well known, regardless of the type of battery, all batteries will have a reduced power storage during charging and discharging. The situation, and the battery has a certain service life, therefore, in the battery production, it is necessary to perform a complete discharge before fully charging to ensure that the maximum storage capacity of the battery is normal and maintain a certain degree of service life. The conventional battery production device includes a discharge unit and a charging unit, and the conventional battery production device is connected to at least one battery, whereby the conventional battery production device is operated by the discharge unit. The battery is completely discharged directly, and after the discharge is completed, the charging unit directly charges the battery until it is full, but with the global energy shortage, the power required for charging is increased, resulting in an increase in production costs.

Therefore, how to solve the above problems and deficiencies in the above-mentioned applications, that is, the inventors of the present invention and those involved in the industry are eager to study the direction of improvement.

Therefore, in view of the above-mentioned deficiencies, the inventors of the present invention have collected relevant materials, and through multi-party evaluation and consideration, and through years of experience accumulated in the industry, through continuous trial and modification, the design has been designed to reduce production costs and save. A patented manufacturer of a smart scheduling system and method for testing a battery using electricity.

The main object of the present invention is to reduce electricity costs and power consumption.

In order to achieve the above object, the present invention is for charging and discharging at least one power storage element, and the main structure includes at least one charging and discharging device electrically connected to the power storage device, and the charging and discharging device is connected with a central control module. And the charging and discharging device is electrically connected to a DC electric switching device, and the DC switching device is electrically connected to an energy conversion device, and the energy conversion device is connected to the mains; and the central control module is charged when the invention is activated. The discharge device discharges the storage element, and the discharged current is transmitted to the DC power exchange device and the energy conversion device for sale to the commercial power, and after the discharge process is completed, the charge and discharge device charges the storage element, and the central control mode is performed. The group is selectively delayed after the start of the discharge process to cause another charge and discharge device that has not performed the discharge process to discharge the power storage device that is not subjected to the discharge process, and the power discharged at this time is transmitted to the DC power exchange device. And the DC power exchange device preferentially transmits the power generated by the charging process. The charging and discharging device that performs the charging process charges the power storage element, or obtains the commercial power from the energy conversion device for charging, and the above technology can break through the problem of the production cost of the conventional battery production device, thereby achieving a reduction. Production cost and practical progress in saving electricity.

1‧‧‧Central Control Module

2‧‧‧Charge and discharge device

3‧‧‧Power storage components

4‧‧‧DC switching device

5‧‧‧ energy conversion device

6‧‧‧Power

A‧‧‧First charging and discharging module

B‧‧‧Second charging and discharging module

C‧‧‧The third charging and discharging module

The first figure is a block diagram showing the structure of a preferred embodiment of the present invention.

Figure 2A is a schematic diagram of the power-backing step of the preferred embodiment of the present invention.

The second B diagram is a schematic diagram of the recharge chart of the preferred embodiment of the present invention.

The second C diagram is a schematic diagram of the discharge of the preferred embodiment of the present invention.

The second D diagram is a schematic diagram of the recharging of the preferred embodiment of the present invention.

The second E diagram is another schematic diagram of the discharge of the preferred embodiment of the present invention.

The second F diagram is a schematic diagram of the charging of the preferred embodiment of the present invention.

The third A is a schematic diagram of the step of saving the cost of the preferred embodiment of the present invention.

Figure 3B is a schematic diagram of a segmentation diagram of a preferred embodiment of the invention.

Figure 4A is a schematic diagram of the step-back charging step of the preferred embodiment of the present invention.

Figure 4B is a schematic diagram of a segmented refill chart of a preferred embodiment of the present invention.

In order to achieve the above objects and effects, the technical means and the structure of the present invention will be described in detail with reference to the preferred embodiments of the present invention.

Referring to the first embodiment, which is a block diagram of a preferred embodiment of the present invention, it will be apparent from the drawings that the present invention is for charging and discharging at least one power storage element 3, and includes at least one charge and discharge. The device 2, a central control module 1, a DC power exchange device 4, and an energy conversion device 5, and the charge and discharge device 2 is electrically connected to the power storage device 3 for charging and discharging, and the central control module 1 is The information connection charging and discharging device 2 is configured to control the timing and scheduling of the operation, and the DC power exchange device 4 is electrically connected to the charging and discharging device 2, and the energy conversion device 5 is electrically connected to the DC power exchange device 4, and the energy conversion device The fifth system is connected to the commercial power supply 6 for charging the electric storage device 3, and the central control module 1 is configured to connect a plurality of charging and discharging devices 2 with information, and the charging and discharging device 2 electrically connects the plurality of electric storage devices 3, and then In the embodiment, a plurality of different charging and discharging devices 2 and power storage elements 3 are divided into a first charging and discharging module A, a second charging and discharging module B, and a third charging and discharging module C for explanation. One of the inventions According to the aspect, the aspect is not limited to this.

Please refer to the first to second F diagrams at the same time, which is a schematic block diagram of a preferred embodiment of the present invention, a schematic diagram of a recharging power saving step, a schematic diagram of a recharging chart, a discharging diagram, a recharging diagram, and another discharging diagram. And the charging diagram, it can be clearly seen from the figure that: [1] at least one charging and discharging device 2 is connected to at least one power storage component 3 by a central control module 1 (the first charging and discharging module A is shown in the figure) As a solution, the discharge process is performed, and the discharged current is transmitted to the DC power exchange device 4, and the current is resold to the commercial power 6 via an energy conversion device 5 (as shown in FIG. 2C), and the charge and discharge device is completed after the discharge process is completed. 2 is a charging procedure for the storage element 3; [2] the central control module 1 is delayed after the start of the discharge program to cause another charging/discharging device 2 that has not performed the discharging process to store power to another non-discharging program. The component 3 (in the figure, the second charging and discharging module B is used as an explanation) performs a discharging process, and the power discharged at this time is transmitted to the DC power exchange device 4, and the DC power exchange device 4 determines whether there is any charging or discharging. The device 2 performs a charging process, and if the charging/discharging device 2 transmits the power to the charging and discharging device 2, the charging element 3 (in the figure, the first charging and discharging module A is used as an explanation) is charged (for example, the second D)), if no power is transmitted to the energy conversion device 5 for resale to the commercial power 6 (as shown in the second E diagram).

Thereby, the power released by the second charging and discharging module B is saved to save the required amount of electricity.

When the charging and discharging device 2 (the first charging and discharging module A) performs the charging process in the step [2], if the DC power exchange device 4 determines that there is no other charging and discharging device 2 (such as the second charging and discharging module B or the third The charging and discharging module C) is performing a discharging process, and the commercial power 6 is connected via the energy conversion device 5 to charge the electric storage device 3 (the first charging and discharging module A) (for example, the second F diagram).

Please refer to the first figure, the third A figure and the third B figure at the same time, which is a schematic diagram of the structure of the preferred embodiment of the present invention, a schematic diagram of the step of saving the cost, and a schematic diagram of the segmentation chart, which is clear from the figure. The method is as follows: [1] The central control module 1 causes at least one charging and discharging device 2 to discharge the at least one electrical storage device 3 during the first time period; [2] and causes the charging and discharging device 2 to be in the second time period. The charging element 3 is charged.

The first time period is a peak power consumption period in which the electricity cost is relatively high, and the second time period is a peak power consumption period in which the electricity cost is relatively low, thereby reducing the electricity cost and saving the production cost.

Please refer to FIG. 1 , FIG. 4A and FIG. 4B together for a schematic diagram of a block diagram of a preferred embodiment of the present invention, a schematic diagram of a stepped refilling step, and a schematic diagram of a segmented recharge chart. It can be clearly seen that the method is as follows: [1] A central control module 1 causes at least one charge and discharge device 2 to at least one power storage device 3 in the first period of time (the first charging and discharging module A is illustrated in the figure) Performing a discharge process, and the discharged current is resold to the commercial power 6 via the DC power exchange device 4 and an energy conversion device 5; [2] The charge and discharge device 2 is placed on the storage element 3 in the second period after the discharge process is completed (first) The charging and discharging module A) performs a charging process, and the central control module 1 delays the charging/discharging device 2 that has not been subjected to the discharging process to another storage element 3 that has not been subjected to the discharging process after the start of the discharging process ( For example, in the second charging and discharging module B or the third charging and discharging module C, in the illustrated embodiment, the discharging process is performed by using the third charging and discharging module C as an explanation, and the discharged power is transmitted to the DC power exchange device 4; 〕 DC power exchange device 4 is to determine if there is any charge The electric device 2 (the first charging and discharging module A) performs a charging process, and if the charging/discharging device 2 that transmits the electric power to the charging program is charged to the electric storage device 3 (the first charging and discharging module A), No electricity is transmitted to the energy conversion device 5 for resale to the utility power 6.

The first time period is a peak power consumption period in which the electricity cost is relatively high, and the second time period is a peak power consumption period in which the electricity cost is relatively low, and the charging and discharging device 2 (the first charging and discharging module A) is charged. In the program, if the DC power exchange device 4 determines that the other charging/discharging device 2 (the second charging/discharging module B or the third charging and discharging module C) is performing the discharging process, the mains 6 is connected via the energy conversion device 5 to store electricity. The component 3 (the first charging and discharging module A) is charged.

Therefore, the smart scheduling system of the battery test production method of the present invention and the method thereof can improve the conventional technology. The key is to cooperate with the central control module 1, the charging and discharging device 2, and the DC power exchange device 4 to achieve the present invention. Reduce production costs and save practical use of electricity.

However, the above description is only for the preferred embodiment of the present invention, and thus the scope of the present invention is not limited thereto, so that the simple modification and equivalent structural changes that are made by using the specification and the contents of the present invention should be the same. It is included in the scope of the patent of the present invention and is combined with Chen Ming.

In summary, the smart scheduling system and method of the battery test production of the present invention can achieve its efficacy and purpose when used, so the invention is an invention with excellent practicability, and is an application for conforming to the invention patent. The essentials, 提出 apply in accordance with the law, and hope that the trial committee will grant the invention as soon as possible to protect the inventor's hard work. If there is any doubt in the arbitral tribunal, please do not hesitate to give instructions, the inventor will try his best to cooperate and feel polite.

1‧‧‧Central Control Module

2‧‧‧Charge and discharge device

3‧‧‧Power storage components

4‧‧‧DC switching device

5‧‧‧ energy conversion device

6‧‧‧Power

A‧‧‧First charging and discharging module

B‧‧‧Second charging and discharging module

C‧‧‧The third charging and discharging module

Claims (9)

A smart scheduling system for battery test production, the smart schedule system is for charging and discharging at least one power storage component, and the smart schedule system comprises: at least one charge and discharge device, the charge and discharge device and the power storage component Electrically connected for charging and discharging; a central control module, the central control module is connected to the charging and discharging device, and controls the timing and scheduling of charging and discharging directly or at a specific time; a DC power exchange device electrically connected to the discharge device, wherein the DC power exchange device determines whether any of the charge and discharge devices is performing a charging process to selectively control the current to charge or resell the power storage device to the charge and discharge device that performs the charging process And an energy conversion device electrically coupled to the DC power exchange device to convert a voltage. The smart scheduling system for battery test production according to claim 1, wherein the central control module is configured to connect a plurality of the charging and discharging devices, and the charging and discharging device electrically connects the plurality of the electrical storage elements. The smart metering system for battery test production according to claim 1, wherein the energy conversion device is coupled to a commercial power source for charging the power storage element. A method for intelligently scheduling a battery test production by: causing at least one charge and discharge device to discharge a current storage component by a central control module, and discharging the current to the DC power exchange device, and The current is resold to the mains via an energy conversion device, and after the discharge process is completed, the charging and discharging device performs a charging process on the storage element, and the central control module is delayed after the start of the discharging process to cause another The charge and discharge device of the discharge program performs a discharge process on another power storage element that has not been subjected to the discharge process, and the power discharged at this time is transmitted to the DC power exchange device, and the DC power exchange device determines whether any charge and discharge device is charging. Program, if any, is to transfer the power to the charging process The discharge device charges the power storage element, and if not, the power is transmitted to the energy conversion device and resold to the commercial power. The method for intelligently scheduling battery test production according to claim 4, wherein when the charge and discharge device performs a charging process, if the DC switch device determines that no other charge and discharge device is performing the discharge process, The energy conversion device is connected to the commercial power to charge the power storage element. A method for intelligently scheduling a battery test production by: causing at least one charge and discharge device to discharge at least one power storage device by a central control module during a first period of power consumption of a relatively high power charge, and The charging and discharging device charges the storage element in a second period of off-peak power consumption at a relatively low electricity rate to reduce the electricity bill. A method for intelligently scheduling a battery test production by: causing at least one charge and discharge device to discharge a current storage component by a central control module during a first period of time, and discharging the current through the DC power exchange device And an energy conversion device is resold to the commercial power, and the charging and discharging device is caused to charge the storage element during the second time period after the discharging process is completed, and further, the central control module is delayed after the start of the discharging process A charging/discharging device that has not performed a discharging process performs a discharging process on another storage element that has not been subjected to a discharging process, and the discharged power is transmitted to the DC switching device, and the DC switching device determines whether any charging/discharging device is in progress. The charging program charges the power storage element when the power is transmitted to the charging and discharging device that performs the charging process, and the power is not transmitted to the energy conversion device for resale to the commercial power. The method for intelligently scheduling battery test production according to item 7 of the patent application, wherein the first time period is a peak power consumption period in which the electricity cost is relatively high, and the second time period is a relatively low electricity cost. The peak power usage period, thereby reducing the electricity bill. The method of intelligent scheduling of battery test production as described in claim 7 of the patent scope, When the charging/discharging device performs the charging process, if the DC power exchange device determines that no other charging/discharging device is performing the discharging process, the commercial device is connected via the energy conversion device to charge the storage element.