IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0100825
(2008-04-10)
|
등록번호 |
US-8479886
(2013-07-09)
|
우선권정보 |
JP-2007-103773 (2007-04-11) |
발명자
/ 주소 |
- Tokuyama, Harumichi
- Mori, Masahiko
- Takami, Makoto
- Kikuchi, Haruhiko
- Yoshinaga, Akira
- Sasaki, Noriyuki
- Itani, Shinya
|
출원인 / 주소 |
- Toshiba Kikai Kabushiki Kaisha
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
5 인용 특허 :
6 |
초록
▼
A lubrication-condition detector detects a lubricant shortage of a target portion that repeats a predetermined operation at a predetermined cycle. The lubrication-condition detector includes: a physical-quantity measuring unit for continuously measuring a physical quantity related to the target port
A lubrication-condition detector detects a lubricant shortage of a target portion that repeats a predetermined operation at a predetermined cycle. The lubrication-condition detector includes: a physical-quantity measuring unit for continuously measuring a physical quantity related to the target portion; and a computer for determining a presence of a lubricant shortage based on the physical quantity. The computer includes: a cycle extractor for extracting a cycle datum per an operational cycle from continuous data including the physical quantity and its measuring time; a representative-value calculator for calculating a representative value for each of plural cycle data; and determining unit for determining a presence of a lubricant shortage based on the plural representative values.
대표청구항
▼
1. A lubrication-condition detector that detects a lubricant shortage of a target portion, the target portion comprising: a fixed member; a movable member that repeats a predetermined operation relative to the fixed member at a predetermined cycle; a driver that drives the movable member; and a lubr
1. A lubrication-condition detector that detects a lubricant shortage of a target portion, the target portion comprising: a fixed member; a movable member that repeats a predetermined operation relative to the fixed member at a predetermined cycle; a driver that drives the movable member; and a lubricant that lubricates the movable member between the fixed member and the movable member, the lubrication-condition detector comprising: a physical-quantity measuring unit that continuously measures a physical quantity related to the target portion; anda computer that determines a presence of a lubricant shortage of the target portion based on the physical quantity measured by the physical-quantity measuring unit, wherein the computer comprises: a cycle extractor that extracts for each operational cycle plural values of the physical quantity from continuous measurements of the physical-quantity measuring unit and a measuring time thereof, the plural values of the physical quantity being associated with the movable member as it moves through the operational cycle;a representative-value calculator that calculates plural representative values for each of A plurality of operational cycles, each of the representative values being calculated from the plural values extracted by the cycle extractor for the corresponding operational cycle, wherein the representative value is one of a maximum value, a minimum value, an average value, an effective value or a variation value of the physical quantity measured in the operational cycle; anda determining unit that determines a presence of a lubricant shortage of the target portion based on the representative values calculated by the representative-value calculator for corresponding plural operational cycles. 2. The lubrication-condition detector according to claim 1, wherein the determining unit determines a presence of a lubricant shortage of the target portion based on time-series transition of the representative values of continuous plural cycles. 3. The lubrication-condition detector according to claim 2, wherein, the physical quantity measured by the physical-quantity measuring unit is electric current, electric resistance or electric potential difference between the fixed member and the movable member of the target portion. 4. The lubrication-condition detector according to claim 2, wherein the driver of the target portion comprises a motor for operating the movable member, and the physical value measured by the physical-quantity measuring unit is torque or electric current of the motor. 5. The lubrication-condition detector according to claim 1, wherein, the physical quantity measured by the physical-quantity measuring unit is electric current, electric resistance or electric potential difference between the fixed member and the movable member of the target portion. 6. The lubrication-condition detector according to claim 1, wherein the driver of the target portion comprises a motor for operating the movable member, and the physical value measured by the physical-quantity measuring unit is torque or electric current of the motor. 7. A lubricant feeder, comprising: the lubrication-condition detector according to claim 1; anda feeder that feeds the lubricant to the target portion when the lubrication-condition detector detects a lubricant shortage of the target portion. 8. The lubricant feeder according to claim 7, wherein the lubrication-condition detector separately detects lubricant shortages of plural target portions, andthe feeder feeds the lubricant only to a target portion where a lubricant shortage is detected among the plural target portions. 9. The lubricant feeder according to claim 7, wherein an alarm notifier that notifies a lubricant shortage(s) of the target portion(s) detected by the lubrication-condition detector by an alarm. 10. An injection molding machine, comprising the lubricant feeder according to claim 7. 11. The injection molding machine of claim 10 wherein the determining unit determines a presence of a lubricant shortage of the target portion based on time-series transition of the representative values of continuous plural cycles. 12. The injection molding machine of claim 10, wherein, the physical quantity measured by the physical-quantity measuring unit is electric current, electric resistance or electric potential difference between the fixed member and the movable member of the target portion. 13. The lubricant feeder of claim 7 wherein the determining unit determines a presence of a lubricant shortage of the target portion based on time-series transition of the representative values of continuous plural cycles. 14. The lubricant feeder of claim 7, wherein, the physical quantity measured by the physical-quantity measuring unit is electric current, electric resistance or electric potential difference between the fixed member and the movable member of the target 15. A method of detecting lubrication condition for detecting a lubricant shortage of a target portion, the target portion comprising: a fixed member; a movable member that repeats a predetermined operation relative to the fixed member at a predetermined cycle; a driver that drives the movable member; and a lubricant that lubricates the movable member between the fixed member and the movable member, the method comprising: continuously measuring a physical quantity related to the target portion;extracting for each operational cycle plural values of the physical quantity from continuous measurements and a measuring time thereof, the plural values of the physical quantity being associated with the movable member as it moves through the operational cycle;calculating representative values for each of a plurality of operational cycles, each of the representative values being calculated from the plural values extracted for the corresponding operational cycle, wherein the representative value is one of a maximum value, a minimum value, an average value, an effective value or a variation value of the physical quantity measured in the operational cycle; anddetermining a presence of a lubricant shortage of the target portion based on the calculated plural representative values for corresponding plural operational cycles. 16. The method of detecting lubrication condition according to claim 15, wherein the presence of a lubricant shortage of the target portion is determined based on time-series transition of the representative values of continuous plural cycles. 17. The method of detecting lubrication condition according to claim 16, wherein the measured physical quantity is electric current, electric resistance or electric potential difference between the fixed member and the movable member of the target portion. 18. The method of detecting lubrication condition according to claim 16 wherein the driver of the target portion comprises a motor for operating the movable member, and the measured physical value is torque or electric current of the motor. 19. The method of detecting lubrication condition according to claim 15, wherein the measured physical quantity is electric current, electric resistance or electric potential difference between the fixed member and the movable member of the target portion. 20. The method of detecting lubrication condition according to claim 15, wherein the driver of the target portion comprises a motor for operating the movable member, and the measured physical value is torque or electric current of the motor.
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