IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0688414
(2007-03-20)
|
등록번호 |
US-8257053
(2012-09-04)
|
우선권정보 |
JP-2006-190728 (2006-07-11) |
발명자
/ 주소 |
- Hase, Masakazu
- Matsuda, Hiroyuki
|
출원인 / 주소 |
- Hitachi Industrial Equipment Systems Co., Ltd.
|
대리인 / 주소 |
Antonelli, Terry, Stout & Kraus, LLP.
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
2 |
초록
▼
In order to provide a compressed air manufacturing facility which can increase a stability of a supply pressure while obtaining an energy saving effect, in a compressed air manufacturing facility provided with a compressor compressing an air, an electric motor driving the compressor, and an inverter
In order to provide a compressed air manufacturing facility which can increase a stability of a supply pressure while obtaining an energy saving effect, in a compressed air manufacturing facility provided with a compressor compressing an air, an electric motor driving the compressor, and an inverter variably controlling a rotating speed of the electric motor, the compressed air manufacturing facility is provided with a pressure sensor detecting a discharge pressure of the compressor at an upstream side position of a discharge air system connected to a discharge side of the compressor, and a control apparatus computing a pressure loss of the discharge air system in correspondence to a rotating speed of the electric motor, and changing a control range of the discharge pressure of the compressor at the upstream side position of the discharge air system on the basis of the computation in such a manner that a terminal pressure at a downstream side position of the discharge air system comes to a predetermined range, and variably controlling the rotating speed of the electric motor via the inverter in such a manner that the discharge pressure of the compressor detected by the pressure sensor comes to the changed control range.
대표청구항
▼
1. A compressed air manufacturing facility, comprising: a compressor configured to compress air;a discharge air system connected to a discharge side of said compressor;an electric motor configured to drive said compressor;an inverter configured to variably control a rotating speed of said electric m
1. A compressed air manufacturing facility, comprising: a compressor configured to compress air;a discharge air system connected to a discharge side of said compressor;an electric motor configured to drive said compressor;an inverter configured to variably control a rotating speed of said electric motor;a pressure detecting means configured to detect the discharge pressure of said compressor at the upstream side position of said discharge air system;a control apparatus configured to: compute a pressure loss of said discharge air system, the pressure loss being a difference of the discharge pressure of said compressor at the upstream side position of said discharge air system as detected by said pressure detecting means, to a pressure at a downstream side position of said discharge air system, in correspondence to the rotating speed of said electric motor,change a control range of a discharge pressure of said compressor at an upstream side position of said discharge air system, on the basis of the pressure loss computation, in such a manner that a terminal pressure at a downstream side position of said discharge air system falls within a predetermined range,variably control the rotating speed of said electric motor via said inverter such that the discharge pressure of said compressor, as detected by said pressure detecting means, falls within the control range changed by said control apparatus,switch the compressor to an unload operation, when the discharge pressure of the compressor increases up to an unload start pressure, as detected by the pressure detecting means, during a load operation of the compressor,switch the compressor to a load operation, when the discharge pressure of the compressor decreases down to a load return pressure, as detected by the pressure detecting means, during an unload operation of the compressor, andchange the unload start pressure and the load return pressure, such that a terminal pressure of an air discharge system falls within a predetermined range, on the basis of a pressure loss of the discharge air system as computed in correspondence to the rotating speed of said electric motor. 2. A compressed air manufacturing facility as claimed in claim 1, wherein said discharge air system has an auxiliary machinery configured to vary a pressure loss characteristic with age, andwherein said control apparatus is configured to correct the pressure loss of said discharge air system in correspondence to the variation with age of the pressure loss characteristic of said auxiliary machinery. 3. A compressed air manufacturing facility as claimed in claim 1, the control apparatus being further configured to: switch the compressor from a stop state to an operational state, when the discharge pressure of the compressor decreases down to an operation return pressure, as detected by the pressure detecting means, during a time when the compressor is in a stop state; andchange the operation return pressure, such that the terminal pressure of the air discharge system falls within a predetermined range, on the basis of a pressure loss of the discharge air system as computed in correspondence to the rotating speed of said electric motor. 4. A compressed air manufacturing facility, comprising: a compressing means for compressing air;a air discharge means connected to a discharge side of said compressing means;an electric motoring means for driving said compressing means;an inverting means for variably controlling a rotating speed of said electric motoring means;a pressure detecting means for detecting the discharge pressure of said compressing means at the upstream side position of said air discharge means;a control means for: computing a pressure loss of said air discharge means, the pressure loss being a difference of the discharge pressure of said compressing means at the upstream side position of said air discharge means as detected by said pressure detecting means, to a pressure at a downstream side position of said air discharge means, in correspondence to the rotating speed of said electric motoring means,changing a control range of a discharge pressure of said compressing means at an upstream side position of said air discharge means, on the basis of the pressure loss computation, in such a manner that a terminal pressure at a downstream side position of said air discharge means falls within a predetermined range,variably controlling the rotating speed of said electric motoring means via said inverting means such that the discharge pressure of said compressing means, as detected by said pressure detecting means, falls within the control range changed by said control means,switching the compressing means to an unload operation, when the discharge pressure of the compressing means increases up to an unload start pressure, as detected by the pressure detecting means, during a load operation of the compressing means,switching the compressing means to a load operation, when the discharge pressure of the compressing means decreases down to a load return pressure, as detected by the pressure detecting means, during an unload operation of the compressing means, andchanging the unload start pressure and the load return pressure, such that a terminal pressure of an air discharge system falls within a predetermined range, on the basis of a pressure loss of the air discharge means as computed in correspondence to the rotating speed of said electric motoring means. 5. A compressed air manufacturing facility as claimed in claim 4, wherein said air discharge means has an auxiliary machinery for varying, based on age, a pressure loss characteristic, andwherein said control apparatus for correcting the pressure loss of said air discharge means does so in correspondence to the variation with age of the pressure loss characteristic of said auxiliary machinery. 6. A compressed air manufacturing facility as claimed in claim 4, the control means being further for: switching the compressing means from a stop state to an operational state, when the discharge pressure of the compressing means decreases down to an operation return pressure, as detected by the pressure detecting means, during a time when the compressing means is in a stop state; andchanging the operation return pressure, such that the terminal pressure of the air discharge system falls within a predetermined range, on the basis of a pressure loss of the air discharge means as computed in correspondence to the rotating speed of said electric motoring means. 7. A compressed air manufacturing method, comprising: compressing air, using a compressor with a air discharge system connected to a discharge side thereof;driving said compressor, using an electric motor configured;variably controlling a rotating speed of said electric motor, using an inverter;detecting the discharge pressure of said compressor at the upstream side position of said air discharge system, by using a pressure detecting means;computing, using a control apparatus, a pressure loss of said air discharge system, the pressure loss being a difference of the discharge pressure of said compressor at the upstream side position of said air discharge system as detected by said pressure detecting means, to a pressure at a downstream side position of said air discharge system, in correspondence to the rotating speed of said electric motor;changing, using said control apparatus, a control range of a discharge pressure of said compressor at an upstream side position of said air discharge system, on the basis of the pressure loss computation, in such a manner that a terminal pressure at a downstream side position of said air discharge system falls within a predetermined range;variably controlling, using said control apparatus, the rotating speed of said electric motor via said inverter such that the discharge pressure of said compressor, as detected by said pressure detecting means, falls within the control range changed by said control apparatus;switching, using said control apparatus, the compressor to an unload operation, when the discharge pressure of the compressor increases up to an unload start pressure, as detected by the pressure detecting means, during a load operation of the compressor;switching, using said control apparatus, the compressor to a load operation, when the discharge pressure of the compressor decreases down to a load return pressure, as detected by the pressure detecting means, during an unload operation of the compressor; andchanging, using said control apparatus, the unload start pressure and the load return pressure, such that a terminal pressure of an air discharge system falls within a predetermined range, on the basis of a pressure loss of the air discharge system as computed in correspondence to the rotating speed of said electric motor. 8. A compressed air manufacturing method as claimed in claim 7, further comprising: varying a pressure loss characteristic with age, by using said air discharge system which has an auxiliary machinery, andcorrecting the pressure loss of said air discharge system in correspondence to the variation with age of the pressure loss characteristic of said auxiliary machinery, by using said control apparatus. 9. A compressed air manufacturing method as claimed in claim 7, the method further comprising: switching, using said control apparatus, the compressor from a stop state to an operational state, when the discharge pressure of the compressor decreases down to an operation return pressure, as detected by the pressure detecting means, during a time when the compressor is in a stop state; andchanging, using said control apparatus, the operation return pressure, such that the terminal pressure of the air discharge system falls within a predetermined range, on the basis of a pressure loss of the air discharge system as computed in correspondence to the rotating speed of said electric motor.
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