JP2005180203A - Failure data storage system of vacuum pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a failure data storage system of a vacuum pump, in which a failure cause of the vacuum pump can be easily analyzed, and the failure cause of the vacuum pump can be clarified, and the failure data storage system of the vacuum pump, in which an operation condition of the vacuum pump directly before the failure can be easily observed without preparing a centralized monitoring device even in the case of using a plurality of the vacuum pumps. <P>SOLUTION: The failure data storage system of the vacuum pump is provided with at least a sensor 1 to detect the operation condition of the vacuum pump 3, and a recording means 5 to store the operation condition of the vacuum pump 3 in the predetermined period directly before the failure occurrence of the vacuum pump 3 as data. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a failure data storage system for a vacuum pump, and more particularly to a failure data storage system for a vacuum pump used as a vacuum exhaust device of a semiconductor manufacturing apparatus.

  2. Description of the Related Art In a semiconductor manufacturing apparatus, a vacuum exhaust apparatus is widely used to exhaust process gas supplied into a vacuum chamber. For example, in a semiconductor manufacturing apparatus such as a CVD apparatus or an etching apparatus, it is necessary to exhaust a process gas in a vacuum chamber and form a certain vacuum state in the vacuum chamber. A vacuum exhaust device is connected to the vacuum chamber via an exhaust pipe, and the vacuum chamber is exhausted by this vacuum exhaust device. Usually, this type of evacuation apparatus includes a plurality of vacuum pumps, and these vacuum pumps are connected in series.

  The process gas used in the semiconductor manufacturing apparatus contains a reaction product, and when the process gas is introduced into the vacuum pump, the reaction product is solidified and deposited inside the exhaust pipe and the pump casing. When the deposited reaction product accumulates inside the pump casing, the pump rotor and the pump casing are rubbed, the vacuum pump is overloaded, and finally the vacuum pump is stopped. In the case of a batch processing type CVD apparatus, if the vacuum pump is suddenly stopped, the yield of the product is seriously affected. In practice, this is dealt with by periodically replacing the vacuum pump according to the operating time. However, not only does it require maintenance costs, but periodic replacement cannot completely prevent sudden failures.

  On the other hand, the operating state of the vacuum pump is monitored by measuring the current supplied to the motor (hereinafter referred to as the motor current) and the temperature of the exhaust pipe, and signs of changes in the operating state of the vacuum pump are detected to predict failure. Attempts have also been made. However, the motor current often increases immediately before a failure, and even if an abnormal increase in the motor current can be detected, sudden stop of the vacuum pump cannot be avoided. The exhaust pipe temperature is thought to increase due to the reaction heat of the gas flowing through the exhaust pipe, but it is difficult to find an exact relationship between the exhaust pipe temperature and the amount of reaction product deposited or the vacuum pump load. . Therefore, the current situation is that the failure of the vacuum pump due to the reaction product cannot be sufficiently predicted only by the motor current and the exhaust pipe temperature.

Therefore, in order to accurately predict the failure of the vacuum pump, conventionally, the cause of the failure of the vacuum pump has been analyzed using a failure data storage system. FIG. 1 is a schematic diagram showing a conventional vacuum pump failure data storage system. As shown in FIG. 1, the vacuum pump 3 normally has a motor current, a temperature of an exhaust pipe and a vacuum pump, a flow rate of water for cooling the vacuum pump and the motor, and a flow rate of N ₂ gas for diluting the process gas. The operation is performed while the sensor 1 monitors the vacuum pressure and the exhaust pipe pressure. The operation of the vacuum pump 3 is controlled by a CPU (central processing unit) 4 of the control unit 20 based on the output values of these sensors 1, and when the output value of the sensor 1 exceeds a preset threshold value. Is determined that the vacuum pump 3 has failed. In addition, when an evacuation device is constituted by a plurality of vacuum pumps 3, the operation state of these vacuum pumps 3 is monitored via the communication port 10 by a centralized monitoring device.

  The control unit 20 includes a recording device 30 connected to the CPU 4, and when the output value of the sensor 1 exceeds a threshold value, the failure occurrence date and time and the failure content are changed from the CPU 4 to the failure history area 9 of the recording device 30. Is stored as a failure history (failure data). Thus, conventionally, the cause of the failure of the vacuum pump 3 has been estimated based on the failure history stored in the failure history area 9 of the recording device 30.

  However, in recent years, a wide variety of vacuum pumps have been used, and it has become impossible to accurately identify the cause of a vacuum pump failure only by a failure history. In addition, as described above, when monitoring the operating states of a plurality of vacuum pumps, it is necessary to use a centralized monitoring device, which increases the manufacturing cost of the vacuum pump.

  The present invention has been made in view of the above-described conventional problems, can facilitate the analysis of the cause of the vacuum pump failure, and can clarify the cause of the vacuum pump failure. The object is to provide a data storage system. Further, the present invention provides a fault data storage system for a vacuum pump that can easily observe the operating state of the vacuum pump immediately before the fault without providing a centralized monitoring device even when a plurality of vacuum pumps are used. With the goal.

  In order to achieve the above object, according to one aspect of the present invention, at least one sensor that detects an operation state of a vacuum pump and the operation state of the vacuum pump in a predetermined period immediately before the occurrence of a failure of the vacuum pump are stored as data. A fault data storage system for a vacuum pump.

  In a preferred aspect of the present invention, the recording means stores the work area for temporarily storing the operation status of the vacuum pump detected by the sensor as data, and the data in a predetermined period immediately before the failure of the vacuum pump. And a save area for acquiring and saving from the work area.

In a preferred aspect of the present invention, the number of storage histories, the storage period, and the storage interval of data stored in the work area can be adjusted.
A preferred aspect of the present invention is characterized by comprising transmission means for transmitting data stored in the recording means for a predetermined period immediately before the occurrence of a failure of the vacuum pump to the outside.

  Another aspect of the present invention is a vacuum pump comprising the failure data storage system.

  According to the present invention, it is possible to easily analyze the cause of the failure of the vacuum pump by acquiring data indicating the operation state until the vacuum pump breaks down, thereby clarifying the cause of the failure. Can do. As a result, the failure prediction of the vacuum pump can be accurately performed based on the analyzed cause of failure, and the sudden failure of the vacuum pump can be avoided.

  Hereinafter, a failure data storage system for a vacuum pump according to an embodiment of the present invention will be described with reference to FIG. FIG. 2 is a schematic diagram showing a vacuum pump failure data storage system according to an embodiment of the present invention.

As shown in FIG. 2, the failure data storage system includes various sensors 1 that detect the operating state of the vacuum pump 3 and a control unit 2 that is connected to the sensor 1. The sensor 1 includes a current supplied to a motor that is a driving source of the vacuum pump 3, a temperature of the vacuum pump 3 and an exhaust pipe (not shown), a flow rate of water for cooling the vacuum pump and the motor, and a process gas. The flow rate of N ₂ gas for dilution, the vacuum pressure, the pressure of the exhaust pipe, and the like are measured, and each output (measured value) of these sensors 1 is sent to the control unit 2.

  The control unit 2 has a CPU (central processing unit) 4 and a recording device (recording means) 5, and the output of the sensor 1 is sent to the recording device 5 via the CPU 4. In the CPU 4, threshold values are set in advance for the measurement objects of the sensor 1 such as the motor current and the temperature of the vacuum pump 3. The CPU 4 determines that a failure has occurred in the vacuum pump 3 when the output (measured value) of the sensor 1 exceeds a threshold value.

  The recording device 5 stores the operation state of the vacuum pump 3 detected by the sensor 1, that is, the work area 7 for temporarily storing the output value of the sensor 1 as data, and data in a predetermined period immediately before the occurrence of the failure of the vacuum pump 3. A save area 8 that is acquired from the work area 7 and stored, and a failure history area 9 that stores data stored in the save area 8 and the date and time of occurrence of the failure are provided. As the recording device 5, a recording medium such as a memory or an HDD (hard disk) is used.

  The output of the sensor 1 is sent to the recording device 5 via the CPU 4 and recorded in the work area 7 as data indicating the operating state of the vacuum pump 3. The data stored in the work area 7 is regularly updated, and the number of storage histories, the storage period, and the storage interval of the data stored in the work area 7 can be adjusted. For example, the output value of the sensor 1 can be stored in the work area 7 for several tens of seconds at intervals of several minutes. The number of storage histories, the storage period, and the storage interval are set according to the use of the vacuum pump 3, and the upper limit is determined according to the capacities of the work area 7 and the save area 8.

  When the CPU 4 determines that a failure has occurred in the vacuum pump 3, the data stored in the work area 7 is automatically transmitted to the save area 8 and stored in the save area 8. In this case, only data for a predetermined period immediately before the occurrence of the failure of the vacuum pump 3 is stored in the save area 8 from the work area 7. This predetermined period can be determined in accordance with the type and application of the vacuum pump 3, whereby a data amount sufficient for analyzing the cause of the failure of the vacuum pump 3 can be stored in the save area 8.

  The data stored in the save area 8 is transmitted to the failure history area 9 and stored as failure data together with the date and time when the failure occurred. The failure data stored in the failure history area 9 can be transmitted to the outside via the communication port (transmission means) 10. For example, the failure data may be downloaded to an external personal computer connected via the communication port 10 and the cause of the failure of the vacuum pump 3 may be analyzed using this personal computer. As described above, according to the present invention, failure data immediately before a vacuum pump failure can be acquired, so that the cause of the failure of the vacuum pump can be accurately analyzed based on the failure data.

It is a schematic diagram which shows the failure data storage system of the conventional vacuum pump. It is a mimetic diagram showing a failure data storage system of a vacuum pump concerning one embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sensor 2,20 Control part 3 Vacuum pump 4 CPU
5,30 Recording device 7 Work area 8 Save area 9 Failure history area 10 Communication port

Claims (5)

At least one sensor for detecting the operating state of the vacuum pump;
A failure data storage system for a vacuum pump, comprising: a recording unit that stores the operation status of the vacuum pump in a predetermined period immediately before the failure of the vacuum pump as data.   The recording means acquires from the work area a work area for temporarily storing the operation status of the vacuum pump detected by the sensor as data, and the data for a predetermined period immediately before the occurrence of the failure of the vacuum pump. The failure data storage system for a vacuum pump according to claim 1, further comprising a save area for storing.   The fault data storage system for a vacuum pump according to claim 2, wherein the storage history number, storage period, and storage interval of data stored in the work area are adjustable.   4. The vacuum pump according to claim 1, further comprising a transmission unit configured to transmit data stored in the recording unit for a predetermined period immediately before the occurrence of the failure of the vacuum pump to the outside. 5. Fault data storage system. A vacuum pump comprising the failure data storage system according to any one of claims 1 to 4.

Images