KR100967664B1 - Appratus for memory backup of DPF mornitoring apparatus and Method for memory backup using the same - Google Patents

Abstract

The present invention relates to a memory backup device of the DPF monitoring device for recording the operating state of the DPF device, and a DPF memory backup method using the same. The memory backup device of the DPF monitoring device according to the present invention includes: an RTC for outputting a current time; A temperature sensor and a pressure sensor for measuring a temperature and a pressure of a DPF device, a first memory and a second memory in which a current time output from the RTC and a temperature value and a pressure value of the DPF device are stored and connected in parallel with each other; And a controller for storing the current time, the pressure value, and the temperature value in a first memory and a second memory. The memory backup method of the DPF monitoring apparatus includes a current time from an RTC, a temperature sensor, and a pressure sensor when a diesel engine is driven. And a data collection step of receiving pressure and temperature, and storing the current time, temperature value, and pressure value input in the data collection step in a first memory. A first memory storage step, a second memory storage step of storing the current time, pressure, and temperature input in the data collection step in a second memory; and determining whether the diesel engine is terminated, the diesel engine is being driven. And an engine shutdown determination step of feeding back to the data collection step.

DFP, Monitor, Memory, Backup, Synchronization

Description

Apparatus for memory backup of DPF mornitoring apparatus and Method for memory backup using the same}

The present invention relates to a DPF device which is a post-processing device of a diesel engine, and more particularly, to a memory backup device of a DPF monitoring device for recording an operating state of a DPF device and a DPF memory backup method using the same.

As the severity of air pollution increases, it has been proposed in various pollutant reduction devices and methods for automobiles in which air pollution is the main factor.

Among them, DPF (Diesel Particulate Filter trap) devices are widely used in diesel engines.

Referring to the conventional DPF device through Figure 1, the DPF device 10 provided in the exhaust pipe 11 of the diesel engine, and the temperature sensor 31 and the pressure sensor 32 is provided in the DPF device 10, The DPF monitoring device 20 is connected to the temperature sensor 31 and the pressure sensor 32.

When the diesel engine is operating, the exhaust gas is discharged to the outside through the exhaust pipe 11, and the exhaust gas passes through the DPF device 10 to reduce the pollutants, particularly particulate matter, contained in the exhaust gas.

At this time, by using the temperature sensor 31 and the pressure sensor 32 provided in the DPF device 10 to communicate the presence or failure of the operation of the DPF device 10 so that the driver can determine from the driver's seat.

On the other hand, the DPF monitoring device 20 is equipped with a memory for recording the state of the DPF device 10 obtained through the temperature sensor 31 and the pressure sensor 32.

The DPF monitoring apparatus 20 according to the related art records the operating state of the DPF apparatus 10 in the memory based on the values input from the temperature sensor 31 and the pressure sensor 32. Since the memory is easily available, inexpensive, and detachable from the DPF monitoring device 20, a memory card is mainly used for the DPF monitoring device 20.

The memory card may be taken out of the DPF monitoring device 20 to analyze an operating state of the DPF device 10 through an analysis device such as a PC.

However, the memory card may not read information input from the DPF device 10 due to an electric shock, an internal error, or the like. If the record of the DPF device 10 cannot be read from the memory card, the operating state of the DPF device 10 cannot be analyzed, and thus there is a problem in that the pollutants generated by the driving of the diesel engine cannot be efficiently removed. In addition, there is a problem that can not remove the contaminants are subject to legal sanctions by various exhaust gas regulations.

The present invention has been invented to solve the above problems, by backing up the memory of the DPF monitoring device, a memory backup device of the DPF monitoring device that can recover data in the event of a memory in the DPF monitoring device and the DPF memory using the same The purpose is to provide a backup method.

In order to achieve the above object, the memory backup device of the DPF monitoring apparatus of the present invention includes an RTC outputting a current time, a temperature sensor measuring a temperature of the DPF device, a pressure sensor measuring a pressure of the DPF device, and A first memory configured to store a current time output from the RTC, a temperature value and a pressure value of the DPF device, and a current time output in parallel with the first memory and output from the RTC and a temperature value of the DPF device. And a second memory in which a pressure value is stored, a current time is input from the RTC, a pressure value and a temperature value of a DPF device are input from the pressure sensor and a temperature sensor, and the input current time and pressure value and temperature value are input. And a control unit for storing in the first memory and the second memory.

The controller compares contents stored in the first memory and the second memory, respectively, and synchronizes the first memory with a value stored in the second memory when the contents stored in the first memory and the contents stored in the second memory are different. It is characterized by.

The display may be connected to the control unit, and the controller may compare the contents stored in the first memory and the second memory to display abnormality if the contents stored in the first memory and the contents stored in the second memory are different. It may further include.

In addition, the speaker connected to the control unit, the control unit for comparing the contents stored in the first memory and the second memory, respectively, the speaker stored in the first memory and the content stored in the second memory is different from the speaker It may further include.

In the memory backup method of the DPF monitoring apparatus, the memory backup method of the DPF monitoring apparatus is connected to the temperature sensor and the pressure sensor of the RTC and the DPF apparatus and records the state of the DPF apparatus in the first memory and the second memory, respectively. When the diesel engine is driven, a data collection step of receiving a current time, pressure, and temperature from an RTC, a temperature sensor, and a pressure sensor, and storing the current time, temperature value, and pressure value input in the data collection step in a first memory. A first memory storage step, a second memory storage step of storing the current time, pressure, and temperature input in the data collection step in a second memory; and determining whether the diesel engine is terminated, the diesel engine is being driven. And an engine shutdown determination step of feeding back to the data collection step.

Before the data collection step, the contents stored in the first memory and the contents stored in the second memory are compared, and if the contents stored in the first memory and the contents stored in the second memory are different, the contents stored in the second memory. And a pre-memory synchronization step of synchronizing with the first memory.

Also, before the pre-memory synchronization step, the second memory check step of confirming whether the second memory is mounted, and the first memory check step including a first memory check step of confirming whether or not the first memory is mounted; Can be performed.

In addition, between the data collecting step and the first memory storing step, a first memory checking step is further provided during the operation of checking whether the first memory is mounted, and the first memory checking step is not installed. If determined, it is preferable that the second memory storing step is performed.

According to the memory backup device and the backup method of the DPF monitoring apparatus of the present invention as described above, even if there is an error or an error occurs in the first memory mounted on the DPF monitoring apparatus, the data inputted from the DPF apparatus using the second memory is used. Can be restored

As a result, the DPF device of the diesel engine always operates in a good state, thereby reducing the emission of pollutants due to the operation of the diesel engine, and preventing the pollutant emission above the reference value.

Hereinafter, exemplary embodiments of a memory backup device and a DPF memory backup method of the DPF monitoring apparatus of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram of a memory backup device of the DPF monitoring apparatus according to the present invention.

The memory backup device of the DPF monitoring apparatus according to the present invention includes an RTC 25 outputting a current time, a pressure sensor 32 measuring a pressure of the DPF device 10, and a temperature of the DPF device 10. A first memory 26 for storing a temperature sensor 31, a current time and a state of the DPF device 10, and a state of the DPF device 10 disposed in parallel with the first memory 26; The second memory 27 and the present time is input from the RTC 25, the pressure value and the temperature value of the DPF device 10 is input from the pressure sensor 32 and the temperature sensor 31 The controller 21 stores the same in the first memory 26 and the second memory 27.

The DPF monitoring device is connected to the DPF device 10 of the diesel engine to monitor the DPF device 10.

The RTC 25 is embedded in the DPF monitoring apparatus 20 and outputs a current time. Since the current time is continuously output through the RTC 25, the state of the DPF device 10 at a specific time or accumulated for a predetermined time may be recorded to record the state of the DPF device 10.

The temperature sensor 31 is inserted into the DPF device 10 and outputs an output value according to the temperature of the DPF device 10.

The pressure sensor 32 is connected to the DPF device 10 and outputs a pressure value inside the DPF device 10. At this time, as shown in Figure 1, the pressure sensor 32 is not located inside the high temperature DPF device 10, it is fixed to the vehicle body using the pressure sensor bracket (32a), the DPF device ( 10) is connected to the other end of the pressure hose 32b is connected to one end. Since the pressure sensor 32 does not operate normally at high temperature and is damaged by heat, the pressure of the DPF device 10 is measured by connecting the DPF device 10 and the pressure sensor 32 with a pressure hose 32b.

Reference numeral 33 is a cable for transmitting the output signal of the temperature sensor 31 and the pressure sensor 32.

The first memory 26 stores data input from the RTC 25, the temperature sensor 31, and the pressure sensor 32.

The first memory 26 may be any memory that can store input data, but it is preferable to use a card type memory that can be conveniently installed and detached and can store stored contents even when the power is cut off. For example, by using an SD (Secure Digital) card, CF (Compact Flash) card, MMC (Multi Media Card), T-Flash (TransFlash) card, etc., the stored contents can be maintained even if the power is cut off, and the slot (not shown) Detachable through). Particularly, since the first memory 26 must grasp and analyze the operation state of the DPF device 10 through an external computer or a separate analysis device, the first memory 26 is preferably a memory card detachable from a slot.

The second memory 27 is provided in parallel with the first memory 26. Like the first memory 26, the second memory 27 stores data input from the RTC 25, the temperature sensor 31, and the pressure sensor 32. In this case, like the first memory 26, the second memory 27 may be detachably provided. However, the second memory 27 may not necessarily be detachably provided. In addition, the second memory 27 may also be a nonvolatile memory capable of retaining stored contents even when power is cut off. Specific examples thereof include erasable and programmable read only memory (EP-ROM) and flash memory (Flash memory). It is preferable to

In particular, the second memory 27 causes the contents of the second memory 27 to be synchronized with the first memory 26 in case of an abnormality of the first memory 26.
The controller 21 compares the contents stored in the first memory 26 and the second memory 27, respectively, and the contents stored in the first memory 26 and the contents stored in the second memory 27 are different from each other. In this case, the first memory 26 is regarded as abnormal, that is, an error or damage.
In other words, when data collected in the first memory 26 is stored in the information system, sector-based erasure and sector-based write processes are performed. If the storage process is temporarily interrupted due to carelessness or the like, the contents of the stored sector are all lost. That is, the first memory is abnormal. Therefore, the first memory is reset, and the data is regarded as an error, damaged or lost data. will be.

The controller 21 receives a signal output from the above components and stores the signals in the first memory 26 and the second memory 27.

The control unit 21 receives the current time, temperature value, and pressure value from the RTC 25, the temperature sensor 31, and the pressure sensor 32, respectively, and the first memory 26 and the second memory 27 are inputted thereto. Record each in). The controller 21 allows the data input from the RTC 25, the temperature sensor 31, and the pressure sensor 32 to be simultaneously recorded in the first memory 26 and the second memory 27. When an error or loss of the first memory 26 occurs, the first memory 26 may be synchronized with the contents stored in the second memory 27.

On the other hand, the control unit 21 is connected to the operation panel 22 for receiving input from the user, and is connected to the display 23, the speaker 24 for informing the presence or absence of the abnormality, the status of the DPF device 10 . The user operates the DPF monitoring apparatus 20 through the operation panel 22, or the user's requirements are input to the DPF monitoring apparatus 20. In addition, the operation state of the DPF device 10 and the DPF monitoring device 20, the presence of abnormality, and the like are output through the display 23 and the speaker 24.

Here, the control unit 21 may be further provided with a separate communication unit (not shown). For example, the communication unit capable of wireless communication may be connected to the control unit 21, and the temperature value and the pressure value of the DPF device measured by the DPF monitoring device may be transmitted to the outside using the communication unit. By checking the discharge of pollutants of each vehicle and the abnormality of the DPF device through the communication unit, it is possible to control the discharge of pollutants in a remote, real-time.

Meanwhile, a memory backup method of the DPF monitoring apparatus according to the present invention will be described.

The memory backup method of the PF monitoring apparatus according to the present invention may be implemented by the memory backup apparatus of the PF monitoring apparatus according to the present invention described above.

In the DPF memory backup method of the DPF monitoring apparatus according to the present invention, a pre-memory mounting check step (S110) confirming whether the first memory 26 and the second memory 27 are mounted in the DPF monitoring apparatus 20 before operation. And a pre-memory comparing step (S120) for comparing the contents stored in the first memory 26 and the second memory 27, and synchronizing the contents of the first memory 26 and the second memory 27. Pre-memory synchronization step (S131), the data collection step (S140) that the current time, temperature value, pressure value is input to the control unit 21 when the diesel engine is driven, and the input current time, temperature value, pressure value A first memory storage step S170 for storing in the first memory 26 and a second memory storage step S180 for storing the input current time, temperature value, and pressure value in the second memory 27.

The pre-memory mounting check step (S110) checks whether the memory is mounted in the DPF monitoring apparatus 20. To this end, in the pre-memory check step S110, the second memory check step S111 for checking whether the second memory 27 is mounted and the first memory check whether the first memory 26 is mounted for the second memory 27. It includes a mounting check step (S112).

The reason why the second memory check step S111 is performed before the first memory check step S112 is to back up the contents of the second memory 27 to the first memory 26 in an emergency. This is to confirm the second memory 27 before storing the contents in the first memory 26.

In the pre-memory comparison step (S120), the contents stored in the first memory 26 and the contents stored in the second memory 27 are compared before storing the data input from the DPF device 10. Through the pre-memory comparison step (S120), the identity of the contents stored in the first memory 26 and the contents stored in the second memory 27 are checked.

If the contents stored in the first memory 26 and the contents stored in the second memory 27 are different from each other in the pre-memory comparison step S120, the pre-memory synchronization step 131 is performed. In the pre-memory synchronization step S131, the contents of the second memory 27 are copied to the first memory 26 to synchronize the contents of the first memory 26 with the contents of the second memory 27. In this case, the reference in synchronization between the first memory 26 and the second memory 27 is based on the second memory 27.

On the other hand, if it is determined that the first memory 26 is not mounted in the pre-memory first memory mounting step (S112), the first memory (3) is transmitted to the controller 21 through the pre-memory synchronization flag deleting step (S113). 26 and the second memory 27 are not memorized.

In addition, when it is determined that the contents stored in the first memory 26 and the second memory 27 are the same in the pre-memory comparison step S120 or the pre-memory synchronization step S131 is performed, the controller 21 A pre-memory synchronization flag input step S132 is performed to store that the first memory 26 and the second memory 27 are synchronized.

The above pre-memory mounting check step (S110), the pre-memory comparison step (S120), and the pre-memory synchronization step (S131) are performed by the DPF monitoring device 20 before the DPF device 10 is operated. By comparing and backing up values stored in the first memory 26 and the second memory 27 before the diesel engine is operated, it is possible to prepare for an abnormality of the first memory 26.

In addition, when the DPF monitoring apparatus 20 is operated after the diesel engine is operated, a function of checking whether there is an abnormality between the first memory 26 and the second memory 27 to which data is input from the DPF apparatus 10 in advance. There is also.

Thereafter, when the DPF device 10 is operated together with the operation of the diesel engine, a data collection step (S140) of receiving a current time from the RTC 25 and collecting a temperature value and a pressure value from the DPF device 10 is performed. do. In the data collection step (S140) receives the current time from the RTC 25 receives the time when the data is input, the temperature sensor 31 and the pressure sensor 32 connected to the DPF device 10 from the DPF device ( 10) Input the internal temperature and pressure value. The control unit 21 receives the information on the current time from the RTC 25, temporarily stores the current time in the control unit 21, and inputs the temperature value and the pressure value in real time when the current time is stored. Remember too. As a result, the temperature value and the pressure value at a specific time are temporarily stored in the control unit 21, thereby collecting data.

When data is collected through the data collection step S140, the data is stored in the first memory 26 and the second memory 27, and whether the first memory 26 is installed or not, the first memory 26 is used. And whether the second memory 27 is synchronized.

During the operation, the first memory mounting check step 150 determines whether the first memory 26 to store the current time, temperature value, and pressure value input in the data collection step S140 is mounted. If it is determined that the first memory 26 is not mounted, the collected data is stored only in the second memory 27, and if the first memory 26 is mounted, the first memory 26 and the second memory 27 are stored. At the same time.

If it is determined that the first memory 26 is not mounted, the memory synchronization flag is deleted in the controller 21 so as not to remember whether the first memory 26 and the second memory 27 are synchronized (S151). .

On the other hand, if it is determined that the first memory 26 is mounted, it is checked whether the flag is input to the controller 21 so as to store synchronization of the first memory 26 and the second memory 27 (S161). If a flag is not inputted, the first memory 26 and the second memory 27 are synchronized with respect to the second memory 27 (S162), and a memory synchronization flag is input (S163). If is entered, the process proceeds.

After the data collection step S140 is performed, the collected data is stored in the first memory 26 in which the present time, temperature, and pressure are temporarily stored in the controller 21 for storage. S170 is executed.

In the first memory storage step S170, the data collected by the controller 21 is stored in the first memory 26 through the data collection step S140. The controller 21 sequentially stores the current time, temperature value, and pressure value input from the data collection step S140 in the first memory 26. Therefore, the temperature and pressure values of the DPF device 10 are accumulated and recorded in the first memory 26 through the first memory storage step S170.

Meanwhile, after the first memory storage step S170 is executed, the second memory storage step S180 is executed. The second memory storage step S180 receives and stores a current time, a temperature value, and a pressure value from the controller 21 to the second memory 27 similarly to the first memory storage step S170.

When the first memory storage step S170 and the second memory storage step S180 are performed, the contents stored in the first memory 26 and the contents stored in the second memory 27 are the same.

Therefore, if there is an error in the first memory 26, the data stored in the first memory 26 can be updated at any time with the contents stored in the second memory 27, so that an error occurs in the first memory 26. Even if it occurs, the data input from the DPF device 10 may be restored, and the operation state of the DPF device 10 may be analyzed by separating the first memory 26 from the DPF monitoring device 20.

The process after the data collection step S140 is performed continuously while the diesel engine is being driven. After the second memory storage step S180, the engine termination determination step S190 determines whether the diesel engine is driven. Judging by the time interval, while the diesel engine is driven, it is fed back to the data collection step (S140) to continuously store the current time, temperature value and pressure value in the first memory 26 and the second memory 27, and the diesel When the engine stops, the whole process ends.

On the other hand, after the data collection step (S140) can be transmitted to the temperature value and the pressure value of the DPF device measured by the temperature sensor 31 and the pressure sensor 32 to the outside. The DPF device of the vehicle may be monitored in real time by transmitting the temperature value and the pressure value of the DPF device measured by the DPF monitoring device to the outside through a communication unit connected to the control unit 21. For example, using wireless communication, the DPF monitoring device transmits an abnormality of the DPF device input in real time through the DPF monitoring device together with the identification information of the vehicle to the management server, and the management server recognizes the vehicle through the connected database. In addition, the transmission value is compared with a pre-stored reference value to determine whether the DPF device of each vehicle is operating normally. If it is determined that the DPF device installed in each vehicle is abnormally operated, it is notified to repair or replace the DPF device.

1 is a perspective view showing the appearance of a conventional DPF device and a DPF monitoring device.

Figure 2 is a block diagram of a memory backup device of the DPF monitoring apparatus according to the present invention.

Figure 3 is a flow chart of a DPF memory backup method using a memory backup device of the DPF monitoring apparatus according to the present invention.

Description of the Related Art [0002]

10: DPF device 11: exhaust pipe

20: DPF monitoring device 21: control unit

22: operation panel 23: display

24: speaker 25: RTC

26: first memory 27: second memory

31: temperature sensor 32: pressure sensor

32a: Pressure sensor bracket 32b: Pressure hose

33: cable

Claims (8)

An RTC 25 for outputting a current time; A temperature sensor 31 for measuring the temperature of the DPF device 10; A pressure sensor 32 for measuring the pressure of the DPF device 10; A first memory 26 for storing a current time output from the RTC 25 and a temperature value and a pressure value of the DPF device 10; A second memory 27 disposed in parallel with the first memory 26 and storing a current time output from the RTC 25 and a temperature value and a pressure value of the DPF device 10; The present time is input from the RTC 25, the pressure value and the temperature value of the DPF device 10 are input from the pressure sensor 32 and the temperature sensor 31, and the input present time and pressure value and the temperature value are input. Are stored in the first memory 26 and the second memory 27, and the contents stored in the first memory 26 and the second memory 27 are compared with the contents stored in the first memory 26. And if the contents stored in the second memory (27) are different, synchronize the first memory (26) to a value stored in the second memory (27). delete The method of claim 1, The contents stored in the first memory 26 and the second stored in the first memory 26 by comparing the contents stored in the first memory 26 and the second memory 27, respectively, connected to the controller 21. The memory backup device of the DPF monitoring device, characterized in that it further comprises a display (23) indicating the presence or absence of abnormalities stored in the memory (27). The method of claim 1, The contents stored in the first memory 26 and the second stored in the first memory 26 by comparing the contents stored in the first memory 26 and the second memory 27, respectively, connected to the controller 21. And a speaker (24) for generating an alarm sound when the contents stored in the memory (27) are different. It is connected to the temperature sensor 31 and the pressure sensor 32 of the RTC 25 and the DPF device 10, and records the state of the DPF device 10 in the first memory 26 and the second memory 27, respectively. In the memory backup method of the DPF monitoring apparatus, When the contents stored in the first memory 26 and the contents stored in the second memory 27 are different from each other, the contents stored in the first memory 26 and the contents stored in the second memory 27 are compared. A pre-memory synchronizing step (S131) for synchronizing the contents stored in the second memory 27 to the first memory 26; When the diesel engine is driven, the data collection step of receiving the current time, pressure and temperature from the RTC 25, the temperature sensor 31 and the pressure sensor 32 (S140); A first memory storage step (S170) of storing the current time, temperature value and pressure value input in the data collection step (S140) in the first memory (26); A second memory storage step (S180) of storing the current time, pressure, and temperature input in the data collection step (S140) in a second memory (27); Determining whether the diesel engine is terminated, the data collection step (S140) is performed if the diesel engine is running, DPF memory backup method of the DPF monitoring apparatus, characterized in that the. delete The method of claim 5, Before the pre-memory synchronization step (S131), Pre-memory mounting including a second memory check step (S111) for checking whether the second memory 27 is mounted, and a first memory check step (S112) for checking whether the first memory 26 is mounted. DPF memory backup method of the DPF monitoring apparatus, characterized in that the checking step (S110) is performed. The method of claim 5, Between the data collection step (S140) and the first memory storage step (S170), a first memory check step (S150) is further provided during the operation of checking whether the first memory 26 is mounted. If it is determined that the first memory (26) is not mounted in the first memory check step (S150), the second memory storage step (S180) is executed, DPF memory backup method of the DPF monitoring apparatus.

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