KR101100956B1 - Apparatus for aligning cell voltage value using the pointer array and method thereof - Google Patents

Abstract

An apparatus for aligning cell voltage values using a pointer of the present invention includes: a voltage detector configured to sense a plurality of cell voltage values; A first memory comprising a plurality of arrays for storing a plurality of cell voltage values; A second memory comprising a plurality of arrays storing address values of each of the plurality of arrays of the first memory; And control the plurality of cell voltage values sensed by the sensing unit to be stored in each of the arrays of the first memory, arrange the cell voltage values stored in the array of the first memory in an order of magnitude, and apply the corresponding arrays of the sorted cell voltage values. And a controller for controlling the address values to be sequentially stored in the plurality of arrays of the second memory.

Cell, Voltage, Pointer, Array, CAN

Description

Apparatus for aligning cell voltage value using the pointer array and method

The present invention relates to an apparatus and method for aligning cell voltage values using a pointer. More specifically, the plurality of sensed cell voltage values are controlled to be stored in each array of the first memory, the cell voltage values stored in the array of the first memory are arranged in size order, and the corresponding array of the sorted cell voltage values is arranged. The present invention relates to a cell voltage value alignment device and a method of controlling an address value to be sequentially stored in a plurality of arrays of the second memory.

In a conventional battery stack management system, each cell voltage value is transferred to a monitoring system using CAN communication in order to monitor each cell voltage value of the stack. Accordingly, the user monitors an abnormality of the stack and the cell by using the identification number and the voltage value of each cell in the stack.

However, as the number of cells to be monitored increases, it becomes more difficult for the user to grasp the relationship between the voltage difference between each cell and the minimum and minimum voltage values. Therefore, for the convenience of the user, the minimum and maximum cell voltage values and corresponding cell identification numbers are acquired to transmit CAN communication to the monitoring system so that the user can intuitively understand. In addition, the cell voltage values are sorted in order of magnitude as well as minimum and minimum, and are transmitted to the monitoring system so that the user can easily grasp the operation and state of each cell.

However, the conventional alignment system not only causes a lot of memory waste in the process of sorting the cell voltage values in the order of magnitude and transferring them to the monitoring system, but also consumes a lot of time in comparing the cell voltage values.

Referring to FIG. 1, in the conventional system, in order to obtain cell information after arranging x cell voltage values in descending order of x and high order, array_aCellVol [n] (where n cell voltage values are stored) Array aCell_Asc_value [x + y] (see (b) of FIG. 1) storing the cell voltage value aligned with (a) of FIG. 1 and array_Asc_number [x + y] storing the cell identification number pointing thereto (FIG. 1). (See (c) below). In addition, all cells are subjected to n * (x + y) comparison processes in order to obtain an alignment value of each cell. If you want to sort all the cells, you have to go through n * n comparisons.

Sorting all cells in this conventional manner not only causes a lot of memory waste but also takes a lot of time in comparing cell voltage values.

The present invention has been proposed to solve the above problems,

The detected plurality of cell voltage values are stored in each of the arrays of the first memory, the cell voltage values stored in the array of the first memory are arranged in the order of magnitude, and the corresponding array address values of the sorted cell voltage values are set to the second. An object of the present invention is to provide a method of aligning cell voltage values that can be sequentially stored in a plurality of arrays of memories, thereby minimizing memory waste and reducing execution time required for comparing cell voltage values.

According to a feature of the present invention for achieving the above object, the present invention includes a voltage sensing unit for sensing a plurality of cell voltage values; A first memory comprising a plurality of arrays for storing a plurality of cell voltage values; A second memory comprising a plurality of arrays storing address values of each of the plurality of arrays of the first memory; And control the plurality of cell voltage values sensed by the voltage sensing unit to be stored in each of the arrays of the first memory, sort the cell voltage values stored in the array of the first memory in order of magnitude, and arrange the sorted cell voltage values. And a controller for controlling the corresponding array address values to be sequentially stored in the plurality of arrays of the second memory.

At this time, the communication unit for transmitting the information stored in the second memory to the external monitoring system using CAN communication, characterized in that it further comprises.

In addition, the present invention, (a) detecting a plurality of cell voltage values by the voltage sensing unit; (b) storing, by the control unit, the plurality of cell voltage values detected in the step (a) in the plurality of arrays of the first memory; And (c) arranging, by the control unit, a plurality of cell voltage values stored in the plurality of arrays of the first memory in order of magnitude. And (d) sequentially storing corresponding array address values of the cell voltage values arranged in step (c) in the plurality of arrays of the second memory.

In this case, the communication unit may further include transmitting information stored in the second memory to an external monitoring system using CAN communication.

According to the present invention has the following effects.

According to the cell voltage value sorting method using a pointer according to the present invention, an array storing an existing sorted cell voltage value and an array storing an aligned cell identification number are integrated into one pointer array, thereby reducing memory usage. In addition, there is an effect that the comparison execution time required in the process of comparing the respective cell voltage values can be shortened.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the cell voltage value alignment device and method using a pointer according to the present invention as described above will be described in detail.

2 is a block diagram illustrating a cell voltage value alignment device using a pointer according to an embodiment of the present invention.

Referring to FIG. 2, an apparatus for aligning cell voltage values using a pointer according to the present invention includes a voltage sensing unit 20 for sensing a plurality of cell voltage values in a battery stack 10, and a plurality of cell voltage values for storing a plurality of cell voltage values. The first memory 40 configured as an array, the second memory 50 configured as a plurality of arrays storing address values of each of the plurality of arrays of the first memory 40, and the plurality of voltages detected by the voltage detector 20. The cell voltage values are controlled to be stored in each of the arrays of the first memory 40, the cell voltage values stored in the array of the first memory 40 are sorted in size order, and the corresponding array address values of the sorted cell voltage values are controlled. The controller 30 controls to be sequentially stored in the plurality of arrays of the second memory 50, and the communication unit for transmitting the information stored in the second memory 50 to the external monitoring system 100 using CAN communication. 60 is provided.

The voltage detector 20 detects a plurality of cell voltage values in the battery stack 10. Here, the battery stack is composed of a plurality of cells (cell [0] to cell [n]), and the voltage sensing unit 20 measures voltage values of the plurality of cells in the battery stack, respectively.

The first memory 40 includes a plurality of arrays for storing a plurality of cell voltage values.

It is composed of a plurality of arrays for storing address values of each of the plurality of arrays of the second memory (50).

The controller 30 controls the plurality of cell voltage values sensed by the voltage detector 20 to be stored in each of the arrays of the first memory 40, and controls the cell voltage values stored in the array of the first memory 40. The data is arranged in order, and the corresponding array address values of the sorted cell voltage values are controlled to be sequentially stored in the plurality of arrays of the second memory 50.

The communication unit 60 transmits the information stored in the second memory 50 to the external monitoring system 100 using CAN communication. In addition, the communication unit 60 transmits a user input transmitted from the monitoring system 100 to the control unit 30. Accordingly, the controller 30 selectively extracts information stored in the first memory 40 and the second memory 50 and transmits the information to the monitoring system 100 through the communication unit 60.

3 is a flowchart illustrating a cell voltage value alignment method using a pointer according to an embodiment of the present invention.

First, the present invention uses aCell [n] in which the cell voltage value is stored in the existing cell voltage alignment system, but instead of aCellVol_Asc_number [x + y] and aCellVol_Asc_value [x + y] in which the maximum / minimum cell voltage value is stored. Declare a pointer array of size n. At this time, the initial value of the pointer puts the address value of aCellVol [n].

Referring to FIG. 3, the voltage detector 20 detects a plurality of cell voltage values in the battery stack and transmits the detected cell voltage values to the controller 30 (S10).

Next, the controller 30 stores the plurality of cell voltage values sensed by the voltage detector 20 in a plurality of arrays of the first memory 40 (S20).

The controller 30 arranges the plurality of cell voltage values stored in the plurality of arrays of the first memory 40 in the order of magnitude (S30). Referring to FIG. 4, pCellVol [0] is the minimum cell voltage value and pCellVol [n-1] is the maximum cell voltage value in the pCellVol [n] array. In FIG. 4, the cell voltage values are sorted in ascending order, but the present invention is not limited thereto, and the cell voltage values may be sorted (eg, descending) in various ways according to a design environment and a user setting.

Next, the controller 30 sequentially stores corresponding array address values of the cell voltage values arranged in step S30 in the plurality of arrays of the second memory 50 (S40). In FIG. 4, & aCellVol [n] represents a pointer (address value) in an aCellVol [n] array corresponding to each cell voltage value.

In addition, the controller 30 transfers the information stored in the second memory 50 to the communication unit 60 so that the information stored in the second memory 50 can be transmitted to the external monitoring system 100 through CAN communication. It controls (S50, S60). In this case, the controller 30 may extract and provide as many alignment values as desired by the user according to a user input input through the monitoring system 100.

According to the cell voltage value sorting method using a pointer according to the present invention, an array (aCellVol_Asc_value [x + y] of FIG. 1) and an array (aCellVol_Asc_number [x]) storing an aligned cell voltage number are stored. + y]) is integrated into one pointer array (pCellVol [n] of FIG. 4), thereby reducing memory usage.

Also, if cell voltage values are compared with the existing aCellVol [n] array, the rearrangement of the aCellVol [n] array is not allowed. Therefore, each cell voltage value is compared while maintaining the array. Going through. This is because the cell identification number corresponding to the cell voltage value in the array cannot be obtained because the array number means the cell identification number.

However, comparing the cell voltage values with the pCellVol [n] array that points to the aCellVol [n] array allows the realignment of the pCellVol [n] array so that an alignment algorithm can be applied. Therefore, the cell voltage values can be compared only through a maximum of n * (n-1) / 2 comparison processes, thereby reducing the time required for the comparison.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and a person skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

1 is an exemplary diagram for describing a method of using a memory in a conventional cell voltage value sorting system.

2 is a block diagram illustrating a cell voltage value alignment device using a pointer according to an embodiment of the present invention.

3 is a flowchart illustrating a cell voltage value alignment method using a pointer according to an embodiment of the present invention.

4 is an exemplary diagram for describing a memory usage method of the cell voltage value alignment device of the present invention.

<Explanation of symbols for the main parts of the drawings>

20: voltage detection unit 30: control unit

40: first memory 50: second memory

60: communication unit 100: monitoring system

Claims (4)

A voltage sensing unit sensing a plurality of cell voltage values; A first memory comprising a plurality of arrays for storing a plurality of cell voltage values; A second memory comprising a plurality of arrays storing address values of each of the plurality of arrays of the first memory; And The plurality of cell voltage values sensed by the voltage sensing unit are controlled to be stored in each of the arrays of the first memory, and corresponding array address values are stored in the order of the magnitude of the cell voltage values stored in each of the arrays of the first memory. And a control unit for controlling to be sequentially stored in a plurality of arrays of two memories. The method according to claim 1, And a communication unit for transmitting the information stored in the second memory to an external monitoring system using CAN communication. (a) sensing a plurality of cell voltage values by a voltage detector; (b) storing, by the control unit, the plurality of cell voltage values detected in the step (a) in the plurality of arrays of the first memory; And and (c) sequentially storing, by the control unit, the plurality of cell voltage values stored in the plurality of arrays of the first memory in the plurality of arrays of the second memory in the order of magnitude. Cell voltage value sorting method using a pointer. The method of claim 3, And transmitting information stored in the second memory by a communication unit to an external monitoring system using CAN communication.

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