Compressor device as well as the use of such a compressor device
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F04C-018/16
F04C-023/00
F04C-028/06
F04C-029/02
F04C-029/04
출원번호
US-0380462
(2012-06-27)
등록번호
US-10151313
(2018-12-11)
우선권정보
BE-2012/0119 (2012-02-28)
국제출원번호
PCT/BE2012/000032
(2012-06-27)
§371/§102 date
20140822
(20140822)
국제공개번호
WO2013/126969
(2013-09-06)
발명자
/ 주소
Desiron, Andries Jan F.
출원인 / 주소
ATLAS COPCO AIRPOWER, NAAMLOZE VENNOOTSCHAP
대리인 / 주소
Bacon & Thomas, PLLC
인용정보
피인용 횟수 :
0인용 특허 :
17
초록▼
Compressor device that is at least provided with a screw compressor with a compression chamber that is formed by a compression housing, with a drive motor that is provided with a motor chamber formed by a motor housing and with an outlet for the discharge of compressed air that is connected to a pre
Compressor device that is at least provided with a screw compressor with a compression chamber that is formed by a compression housing, with a drive motor that is provided with a motor chamber formed by a motor housing and with an outlet for the discharge of compressed air that is connected to a pressure vessel via an outlet pipe, whereby the compression housing and the motor housing are connected directly to one another to form a compressor housing, whereby the motor chamber and the compression chamber are not sealed off from one another and whereby the outlet pipe between the pressure vessel and the screw compressor is free of closing means.
대표청구항▼
1. A compressor device comprising: a screw compressor with a compression chamber that is formed by a compression housing, in which a pair of meshed compressor rotors in the form of a screw are rotatably mounted, said compression housing comprising an inlet to the screw compressor for the supply of a
1. A compressor device comprising: a screw compressor with a compression chamber that is formed by a compression housing, in which a pair of meshed compressor rotors in the form of a screw are rotatably mounted, said compression housing comprising an inlet to the screw compressor for the supply of air and an outlet from the screw compressor for the discharge of compressed air, and which is connected to a pressure vessel via an outlet pipe;a drive motor that is provided with a motor chamber formed by a motor housing, in which a motor shaft is rotatably mounted that drives at least one of the aforementioned two compressor rotors;the pressure vessel connected to the screw compressor via the outlet pipe including a separator and a return pipe for returning a fluid to both the screw compressor and drive motor;an air outlet on the pressure vessel for the supply of the compressed air from the pressure vessel to a consumer;a control system for controlling one or more liquid or gas flows in the compressor device; said control system being provided with: an inlet valve on the inlet of the screw compressor; and,a tap or valve to close and open the air outlet of the pressure vessel;wherein the compression housing and the motor housing are connected directly to one another to form a compressor housing, whereby the motor chamber and the compression chamber are not sealed off from one another and the compressor device is configured to supply the fluid through the compressor housing for cooling and lubrication of both the drive motor and the compressor rotors with the fluid,whereby the outlet pipe between the pressure vessel and the screw compressor is free of closing means in order to enable a flow through the outlet pipe in both directions, andwherein, when the screw compressor is stopped, the pressure vessel, the compression chamber, and the motor chamber are configured in a way to remain under a uniform pressure so that little or none of the compressed air is lost. 2. The compressor device according to claim 1, wherein the inlet valve is a non-controlled or self-regulating valve. 3. The compressor device according to claim 2, wherein the inlet valve is a non-return valve. 4. The compressor device according to claim 1, wherein during the operation of the screw compressor, or when the compressed air is drawn off from the pressure vessel by a consumer in the outlet pipe, a mixture of the compressed air and the aforementioned fluid flows. 5. The compressor device according to claim 4, wherein the fluid is an oil and wherein the pressure vessel provided with the oil separator is configured so that, when the aforementioned mixture flows, the oil separator separates the mixture into two flows, on the one hand a flow of compressed air via the air outlet of the pressure vessel and on the other hand a flow of oil via a separate oil outlet on the pressure vessel. 6. The compressor device according to claim 5, wherein an oil return pipe is provided at the oil outlet of the pressure vessel, which is connected to the screw compressor for the reinjection of oil. 7. The compressor device according to claim 6, wherein the oil return pipe is free of self-regulating non-return valves. 8. The compressor device according to claim 6, wherein a part of the oil return pipe is constructed as a radiator that is cooled by means of a forced airflow of surrounding air originating from a fan. 9. The compressor device according to claim 8, wherein a bypass pipe is also provided in the oil return pipe that is affixed in parallel over the part of the oil return pipe with the radiator. 10. The compressor device according to claim 9, wherein the control system comprises one or more controlled valves that are provided in the oil return pipe, and which enables the oil flow to be controlled such that the oil is either driven through the radiator in order to cool the oil, or through the bypass pipe in order not to cool the oil. 11. The compressor device according to claim 1, wherein the air outlet comprises a consumer pipe connected to the pressure vessel that can be closed by the tap or the valve, whereby a section of the consumer pipe is constructed as a radiator that is cooled by means of a forced airflow of surrounding air originating from a fan. 12. The compressor device according to claim 1, wherein the air outlet of the pressure vessel is also equipped with a non-return valve. 13. The compressor device according to claim 1, wherein the screw compressor is a vertical screw compressor, whereby the two compressor rotors have rotor shafts that extend along a first axial direction and a second axial direction and the motor shaft extends along a third axial direction and whereby the aforementioned axial directions of the compressor rotors and the motor shaft are vertical during normal operation of the screw compressor. 14. The compressor device according to claim 13, wherein the motor shaft is directly coupled to one of the rotor shafts of the compressor rotors and extends along an axial direction in line with the axial direction of the rotor shaft of the compressor rotor concerned or that the motor shaft also forms the rotor shaft of one of the compressor rotors. 15. The compressor device according to claim 14, wherein the compression housing forms a base or bottom section of the compressor housing, and that the motor housing forms a head or top section of the compressor housing. 16. The compressor device according to claim 15, wherein the compression chamber provided with the inlet for drawing in air that is provided near a low pressure end of the pair of meshed compressor rotors, wherein this low pressure end is the end of the pair of compressor rotors that is closest to the head of the compressor housing, and the outlet for removing the compressed air is provided near a high pressure end of the pair of meshed compressor rotors, wherein this high pressure end is the end of the pair of compressor rotors that is closest to the base of the compressor housing. 17. The compressor device according to claim 1, wherein a return circuit is provided for removing the fluid from the outlet in a base of the screw compressor, and for returning the removed fluid to a head of the compressor housing. 18. The compressor device according to claim 17, wherein the aforementioned return circuit is formed by the set consisting of the outlet pipe, the pressure vessel and an oil return pipe, whereby during the operation of the compressor device the fluid is driven through the return circuit from the base to the head of the compressor housing as a result of a compressor pressure generated by the compressor device. 19. The compressor device according to claim 18, wherein the outlet pipe is connected to the base of the compressor housing, and the oil return pipe is connected to the head of the compressor housing. 20. The compressor device according to claim 17, wherein the aforementioned return circuit is connected to a cooling circuit for cooling both the drive motor and the screw compressor and through which the fluid can flow from the head of the compressor housing to the base of the compressor housing. 21. The compressor device according to claim 20, wherein the cooling circuit consists of cooling channels that are provided in the motor housing and of the compression chamber itself. 22. The compressor device according to claim 20, wherein the majority of the flow of fluid, that is returned via the return circuit, flows through the cooling circuit. 23. The compressor device according to claim 17, wherein the return circuit is connected to a lubrication circuit for lubricating a motor bearing or motor bearings as well as inlet bearings. 24. The compressor device according to claim 1, wherein each of the compressor rotors have a high pressure end that is supported axially and radially in the compressor housing by means of one or more outlet bearings. 25. The compressor device according to claim 24, wherein a lubrication circuit is provided in a base for lubricating the outlet bearings, consisting of one or more supply channels for the supply of the fluid from the compression chamber to the outlet bearings, as well as one or more outlet channels for the return of the fluid from the outlet bearings to the compression chamber. 26. The compressor device according to claim 1, wherein the compressor rotors have a low pressure end that is only supported radially in the compressor housing by bearings. 27. The compressor device according to claim 1, wherein the motor shaft, at the end opposite the driven compressor rotor, is supported axially and radially in the compressor housing by means of one or more motor bearings. 28. The compressor device according to claim 27, wherein the motor shaft is supported in the compressor housing at its end opposite the driven compressor rotor by bearings, said bearings comprising a motor bearing that is a deep groove ball bearing, and further comprising a tensioning element configured to exert an axial pre-load on the deep groove ball bearing, and this pre-load is oriented along the axial direction of the motor shaft. 29. The compressor device according to claim 1, wherein the drive motor is of a type that can withstand compressor pressure. 30. The compressor device according to claim 1, wherein the drive motor is of a type that can generate a sufficiently large start-up torque to start up the screw compressor when the compression chamber is under compressor pressure. 31. The compressor device according to claim 1, wherein when starting up the screw compressor, whereby no pressure has yet built up in the pressure vessel, the inlet valve is configured to automatically open due to the action of the screw compressor and a compression pressure is built up in the pressure vessel. 32. The compressor device according to claim 31, wherein when the screw compressor is stopped, a non-return valve on the pressure vessel is configured to automatically close the air outlet of the pressure vessel and the inlet valve is configured to also hermetically close an inlet pipe on the inlet of the screw compressor. 33. The compressor device according to claim 32, wherein when the screw compressor restarts, whereby there is still a compression pressure in the pressure vessel, the inlet valve is configured to first automatically remain closed until the compressor rotors reach a sufficiently high speed, after which the inlet valve is configured to automatically open under the suction effect created by the rotation of the compressor rotors. 34. A compressor device comprising: a screw compressor with a compression chamber that is formed by a compression housing, in which a pair of meshed compressor rotors in the form of a screw are rotatably mounted;a drive motor that is provided with a motor chamber formed by a motor housing, in which a motor shaft is rotatably mounted that drives at least one of the aforementioned two compressor rotors;an inlet to the screw compressor for the supply of air;an outlet to the screw compressor for the discharge of compressed air, and which is connected to a pressure vessel via an outlet pipe;an air outlet on the pressure vessel for the supply of the compressed air from the pressure vessel to a consumer;a control system for controlling one or more liquid or gas flows in the compressor device; said control system being provided with: an inlet valve on the inlet of the screw compressor; and,a tap or valve to close and open the air outlet of the pressure vessel;wherein the compression housing and the motor housing are connected directly to one another to form a compressor housing, whereby the motor chamber and the compression chamber are not sealed off from one another and whereby the outlet pipe between the pressure vessel and the screw compressor is free of closing means in order to enable a flow through the outlet pipe in both directions,wherein, when the screw compressor is stopped, the pressure vessel, the compression chamber, and the motor chamber are configured in a way to remain under a uniform pressure so that little or none of the compressed air is lost,wherein the screw compressor is provided with a fluid, with which both the drive motor and the compressor rotors are cooled and lubricated,wherein a return circuit is provided for removing fluid from the outlet in a base of the screw compressor, and for returning the removed fluid to a head of the compressor housing,wherein the return circuit is connected to a lubrication circuit for lubricating a motor bearing or motor bearings as well as inlet bearings, and wherein the lubrication circuit consists of one or more branches of cooling channels in the motor housing for supplying fluid to the motor bearing or the motor bearings, and of outlet channels for the removal of fluid from the motor bearing or the motor bearings up to the inlet bearings from where the fluid can flow in the compression chamber. 35. The compressor device according to claim 34, wherein the flow of the fluid in the lubrication circuit primarily takes place under the effect of gravity. 36. The compressor device according to claim 34, wherein, at the motor bearing or the motor bearings, a reservoir is provided for receiving fluid that is sealed off from the motor shaft by means of a labyrinth seal. 37. A compressor device comprising: a screw compressor with a compression chamber that is formed by a compression housing, in which a pair of meshed compressor rotors in the form of a screw are rotatably mounted, said compression housing comprising an inlet to the screw compressor for the supply of air and an outlet from the screw compressor for the discharge of compressed air, and which is connected to a pressure vessel via an outlet pipe;a drive motor that is provided with a motor chamber formed by a motor housing, in which a motor shaft is rotatably mounted that drives at least one of the aforementioned two compressor rotors;the pressure vessel connected to the screw compressor via the outlet pipe including a separator and a return pipe for returning a fluid to both the screw compressor and drive motor;an air outlet on the pressure vessel for the supply of the compressed air from the pressure vessel to a consumer;a control system for controlling one or more liquid or gas flows in the compressor device; said control system comprising: an inlet valve on the inlet of the screw compressor; and,a tap or valve to close and open the air outlet of the pressure vessel;wherein the compression housing and the motor housing are connected directly to one another to form a compressor housing, whereby the motor chamber and the compression chamber are not sealed off from one another and the compressor device is configured to supply the fluid through the compressor housing for cooling and lubrication of both the drive motor and the compressor rotors with the fluid,whereby the outlet pipe between the pressure vessel and the screw compressor is free of closing means in order to enable a flow through the outlet pipe in both directions, andwherein, when the screw compressor is stopped, the pressure vessel, the compression chamber, and the motor chamber are configured in a way to remain under a uniform pressure so that little of the compressed air is lost, andwherein the screw compressor is a vertical screw compressor, and comprises a first compressor rotor having a first rotor shafts that extends along a first axial direction and a second compressor rotor having a second rotor shaft that extends along a second axial direction, andwherein the motor shaft extends along a third axial direction, and the aforementioned axial directions of the compressor rotors and the motor shaft are vertical during normal operation of the screw compressor, andwherein the motor shaft forms a rotor shaft of one of the compressor rotors, and said rotor shaft is formed as a single piece.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (17)
Paul Kermit D. (Bethlehem PA), Compressor capacity and lubrication control system.
Daniëls, Ivo; De Letter, Tom Maria Albert, Device to prevent the formation of condensate in compressed gas and compressor unit equipped with such a device.
Unnewehr Lewis E. (Michigan City IN) Olsaker Oleif (Michigan City IN) Shoop John C. (LaPorte IN) Klingler Ray (Michigan City IN), Lubricant cooled electric drive motor for a compressor.
Van Dyck Christiaan (Lier BEX), Regulating device with starting and stopping device for screw-type compressors, and starting and stopping device used he.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.