Port arrangement for rotary positive displacement blower

US 4,768,934 A
Filed: 11/18/1985
Issued: 09/06/1988
Est. Priority Date: 11/18/1985
Status: Expired due to Term

First Claim

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1. A rotary blower of the backflow type including:

a housing assembly defining two parallel transversely overlapping cylindrical chambers having internal cylindrical and flat end wall surfaces, the axes of the cylindrical chambers defining a longitudinal direction;

an inlet port and an outlet port opening having, with respect to the longitudinal direction, longitudinal and transverse boundaries defined by and on opposite sides of the housing assembly, said transverse boundaries of each port being disposed on opposite sides of a plane extending longitudinally through the overlapping intersection of the chambers;

meshed, lobed rotors rotatably disposed in the chambers, the rotor lobes formed with a helical twist and therefore each having a lead end and a trailing end in the direction of rotor rotation, the ends of the rotors and lobes sealingly cooperating with the end wall surfaces, the lobes of each rotor having top lands extending between the lead and trailing ends, the top lands sealingly cooperating with the cylindrical wall surface of the associated chamber and being operative to traverse the port boundaries disposed on the associated side of the plane for effecting transfer of volumes of compressible inlet port fluid to the outlet port via spaces between adjacent unmeshed lobes of each rotor, and the volume of each transfer volume remaining constant while the top lands of the leading and trailing lobes of each transfer volume are disposed between the associated boundaries of the inlet and outlet ports;

the improvement comprising;

rapidly opening backflow port means extending through the housing wall of each cylindrical chamber for effecting a backflow of outlet port fluid into each transfer volume prior to traversal of the outlet port boundaries by the top land of the lead lobe of each transfer volume, said backflow port means positioned for traversal by the lead lobe top land of each transfer volume at least 40 rotational degrees after traversal of the inlet port boundaries by the top land of the trailing lobe of each transfer volume.

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Abstract

An improved rotory positive displacement blower (10) of the Roots-type with reduced airborne noise and superior efficiency. The blower includes a housing (12) defining generally cylindrical chambers (32, 34) having cylindrical wall surfaces (20a, 20b) and containing meshed lobed rotors (14, 16) having the lobes (14a, 14b, 14c, 16a, 16b, 16c) thereon formed with an end-to-end helical twist according to the relation 360°/2n, where n equals the number of lobes per rotor. Preferably, n equals three. The blower housing (12) also defines inlet and outlet ports (36, 38) and the intersections of wall surfaces (20a, 20b) define a cusp (20d) associated with the inlet port (36) and a cusp (20e) associated with outlet port (38). The inlet and outlet port openings are skewed in opposite directions to increase the time the top lands of the lobes are in sealing relation with cylindrical walls (20a, 20b) of chambers ( 32, 34). Transverse boundaries (20g, 20i) of the inlet port are traversed by the lobes prior to traversal of the inlet port cusp (20d) by trailing ends (14h, 16h) of the lobes. In a similar manner, the transverse boundaries (20n, 20r) of the outlet port are traversed by the lobes subsequent to traversal of the outlet port cusp (20e) by leading ends (14g, 16g) of the lobes. Elongated backflow slots (40, 42) having a length/width ratio of at least four are disposed on opposite sides of the outlet port cusp and substantially parallel to the traversing lobes of the associated rotor. The backflow slots are traversed by the lobes prior to traversal of cusp (20e) and outlet port boundaries (20n, 20r) by the lobes.

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23 Claims

1. A rotary blower of the backflow type including:
- a housing assembly defining two parallel transversely overlapping cylindrical chambers having internal cylindrical and flat end wall surfaces, the axes of the cylindrical chambers defining a longitudinal direction;
  
  an inlet port and an outlet port opening having, with respect to the longitudinal direction, longitudinal and transverse boundaries defined by and on opposite sides of the housing assembly, said transverse boundaries of each port being disposed on opposite sides of a plane extending longitudinally through the overlapping intersection of the chambers;
  
  meshed, lobed rotors rotatably disposed in the chambers, the rotor lobes formed with a helical twist and therefore each having a lead end and a trailing end in the direction of rotor rotation, the ends of the rotors and lobes sealingly cooperating with the end wall surfaces, the lobes of each rotor having top lands extending between the lead and trailing ends, the top lands sealingly cooperating with the cylindrical wall surface of the associated chamber and being operative to traverse the port boundaries disposed on the associated side of the plane for effecting transfer of volumes of compressible inlet port fluid to the outlet port via spaces between adjacent unmeshed lobes of each rotor, and the volume of each transfer volume remaining constant while the top lands of the leading and trailing lobes of each transfer volume are disposed between the associated boundaries of the inlet and outlet ports;
  
  the improvement comprising;
  
  rapidly opening backflow port means extending through the housing wall of each cylindrical chamber for effecting a backflow of outlet port fluid into each transfer volume prior to traversal of the outlet port boundaries by the top land of the lead lobe of each transfer volume, said backflow port means positioned for traversal by the lead lobe top land of each transfer volume at least 40 rotational degrees after traversal of the inlet port boundaries by the top land of the trailing lobe of each transfer volume.
- View Dependent Claims (2, 3, 4)
- - 2. The rotary blower of claim 1, wherein each rapidly opening backflow port means extends substantially parallel to the traversing top lands.
  - 3. The rotary blower of claim 2, wherein the transverse boundaries of the inlet and outlet ports are disposed substantially parallel to the traversing top lands.
  - 4. The rotary blower of claim 1, wherein the transverse boundaries of the inlet and outlet ports are disposed substantially parallel to the traversing top lands, the backflow port means is a slot extending through the housing wall of each cylindrical chamber and with the length/width ratio of each slot being greater than four and with the lengthwise extent of each backflow slot being substantially parallel to the traversing top lands.

5. A method of reducing airborne noise and improving volumetric efficiency of a Roots-type blower including a housing defining two parallel, longitudinally extending, transversely overlapping, cylindrical chambers having cylindrical and end wall surfaces and having inlet and outlet ports on opposite sides of the housing in the areas where the chambers overlap, the ports each having longitudinal and transverse boundaries respectively defining the longitudinal and transverse extent of the ports;
- meshed lobed rotors rotatably disposed in the chambers, the lobes having a helical twist and therefore a lead end and a trailing end in the direction of rotor rotation, each lobe having a top land extending between the lead and trailing ends and the top land sealingly cooperating with the cylindrical wall surfaces for transferring volumes of compressible fluid from the inlet port to the outlet port in response to traversal of the port boundaries, and the transverse boundaries of the inlet port being disposed for traversal by the top lands prior to traversal of the plane by the trailing end of the top lands;
  
  the method comprising;
  
  maximizing the number of rotational degrees the top lands are in sealing cooperation with the cylindrical wall surfaces by skewing the inlet port opening toward the lead ends of the lobes and the outlet port opening toward the trailing ends of the lobes;
  
  minimizing airborne noise due to backflow of outlet port fluid into the transfer volumes by providing each chamber with rapidly opening backflow port means positioned for traversal by the top land of the lead lobe of each transfer volume at least 40 rotational degrees after the trailing end of the trailing lobe top land traverses the plane and therefore at least substantially 40 rotational degrees after the top land of the trailing lobe of each transfer volume moves into inlet sealing cooperation with the cylindrical wall surfaces of the associated chamber.
- View Dependent Claims (6, 7, 8)
- - 6. The method of claim 5, wherein sealing cooperation of the top lands is further maximized by forming the ports with transverse boundaries substantially parallel to the top lands.
  - 7. The method of claim 6, wherein the airborne noise is further minimized by positioning the rapidly opening backflow ports substantially parallel to the transversing top lands.
  - 8. The method of claim 5, wherein the airborne noise is further minimized by the backflow ports being a slot extending through the housing wall of each cylindrical chamber and providing each slot with a length/width ratio greater than four and with the lengthwise extent of each backflow slot being substantially parallel to the traversing top lands.

9. In a rotary blower of the backflow type including:
- a housing defining two parallel, transversely overlapping cylindrical chambers having internal cylindrical and end wall surfaces, the axes of the cylindrical chambers defining a longitudinal direction and the end walls defining a transverse direction, and each intersection of the cylindrical wall surfaces defining a cusp extending in the longitudinal direction;
  
  an inlet port and an outlet port having longitudinal and transverse boundaries defined by an opening in opposite sides of the housing with the transverse boundaries of each port disposed on opposite sides of a plane extending longitudinally through the cusps;
  
  meshed, lobed rotors rotatably disposed in the chambers, the ends of the rotors and lobes sealingly cooperating with the end wall surfaces, the lobes of each rotor having top lands sealingly cooperating with the cylindrical wall surfaces of the associated chamber and operative to traverse the port boundaries disposed on the associated side of the plane for effecting transfer of volumes of compressible inlet port fluid to the outlet port via spaces between adjacent unmeshed lobes of each rotor, and the volume of each transfer volume remaining constant while the top lands of the leading and trailing lobes of each transfer volume are disposed between the associated boundaries of the inlet and outlet ports;
  
  the improvement comprising;
  
  a backflow port extending completely through a portion of the housing wall of each cylindrical chamber, the backflow ports being transversely spaced from each other on opposite sides of the plane, both backflow ports being on the outlet port side of the housing and both being structurally separated from the inlet and outlet ports by portions of the cylindrical wall surfaces, each backflow port traversed by the top land of the lead lobe of the associated upcoming transfer volume and providing a restricted passage for communicating outlet port fluid to each upcoming transfer volume prior to traversal of the associated outlet port boundaries by the top land of the lead lobe and prior to traversal of the cusp associated with the outlet port side of the housing, and said backflow ports having a length/width ratio greater than four with the lengthwise extent of said backflow ports being substantially parallel to the lengthwise extent of the traversing top lands to facilitate rapid opening of the backflow ports.
- View Dependent Claims (10, 11, 12, 13, 14, 15, 16)
- - 10. The rotary blower of claim 9 wherein the lobes of each rotor are formed with a helical twist whereby each land has a lead end and a trailing end in the direction of rotor rotation and whereby the lengthwise direction of each backflow port being oblique to the axes of the cylinders.
  - 11. The rotary blower of claim 10, wherein the leading edge of each backflow port in the direction of rotor rotation of the associated top lands is positioned for traversal 20-40 rotational degrees prior to traversal of the cusp associated with the outlet port.
  - 12. The rotary blower of claim 11, wherein traversal of the cusp associated with the outlet port by the top land at the leading end of the lead lobe of each upcoming transfer volume occurs prior to traversal of the outlet port boundaries and indirectly communicates the upcoming transfer volume with the outlet port via a transfer volume the of other rotor already in direct communication with the outlet port.
  - 13. The rotary blower of claim 11, wherein the top lands of the lead lobes of each rotor alternately traverse the associated backflow ports and outlet port boundaries x number of rotational degrees apart, wherein x equals (360°
    - )/(2 times the number of lobes per rotor), and wherein the outlet port boundaries are such that an upcoming transfer volume of one rotor communicates indirectly with the outlet port via a transfer volume of the other rotor in response to the top land lead end of the lead lobe of the upcoming transfer volume traversing the cusp associated with the outlet port and prior to the top land of the lead lobe of the upcoming transfer volume traversing the associated boundaries of the outlet port.
  - 14. The rotary blower of claim 10, wherein the inlet port opening is skewed toward the leading ends of the lobes, the outlet port opening is skewed toward the trailing ends of the lobes, and said backflow ports are skewed toward the leading ends of the lobes.
  - 15. The rotatry blower of claim 9, wherein the blower is of the Roots type, each rotor has three lobes formed with a 60°
    - helical twist, whereby each top land has a lead end and a trailing end in the direction of rotor rotation, the transverse boundaries of the inlet and outlet ports are disposed substantially parallel to the associated lobes when traversed, and the top land lead end of the lead lobe of each upcoming transfer volume traverses the associated backflow port prior to traversing the cusp associated with the outlet port.
  - 16. The rotary blower of claim 9, wherein the blower is of the Roots type, each rotor has three lobes formed with a 60°
    - helical twist, the transverse boundaries of the inlet and outlet ports are disposed substantially parallel to the associated lobes when traversed, the top land of the trailing lobe of each tansfer volume is in sealing cooperation with its associated cylindrical wall surface for at least 40 rotational degrees before the top land of the leading lobe of each transfer volume traverses the leading edge of the associated backflow port.

17. A method of reducing airborne noise and improving volumetric efficiency of a Roots-type blower including a housings defining two parallel, transversely overlapping, cylindrical chambers having cylindrical and end wall surfaces with each intersection of the cylindrical wall surfaces defining a cusp partially removed by an inlet and an outlet port opening on opposite sides of the housing;
- helical meshed, lobed rotors rotatably disposed in the chambers, the lobes each having a lead end and a trailing end in their directions of rotation, and the lobes sealingly cooperating with the chamber wall surfaces for transferring volumes of compressible fluid from the inlet port to the outlet port;
  
  the method comprising;
  
  maximizing the number of rotational cylindrical wall surfaces by skewing the inlet port opening toward the lead ends of the lobes and the outlet port opening toward the trailing ends of the lobes, and by positioning the inlet and outlet port boundaries such that trailing ends of the lobes traverse the cusp associated with the inlet port after traversal of the inlet port boundaries and the lead ends of the lobes traverse the cusp associated with the outlet port prior to traversal of the outlet boundaries; and
  
  minimizing airborne noise at a specified blower speed and pressure ratio by positioning an elongated port on opposite sides of the outlet port boundaries for complete traversal by the lobes of the associated rotor within a range of 20- 40 rotational degrees prior to said outlet port cusp traversal and providing said backflow ports with a length/width ratio greater than four and with the lengthwise extent of said backflow ports being substantially parallel to the lengthwise extent of the traversing top lands of the lobes.
- View Dependent Claims (18, 19)
- - 18. The method of claim 17, wherein the twist of the rotor lobes is defined by the relation 360°
    - /2n, where n equals the number of lobes per rotor, and providing said backflow ports with a length/width ratio of at least four.
  - 19. The method of claim 18, wherein n equals two or three.

20. A rotary blower of the backflow type including:
- a housing assembly defining two parallel, transversely overlapping cylindrical chambers having internal cylindrical and flat end wall surfaces, the axis of the cylindrical chambers defining a longitudinal direction;
  
  an inlet port and an outlet port having, with respect to the longitudinal direction, longitudinal and transverse boundaries defined by and on opposite sides of the housing assembly, said transverse boundaries of each port being disposed on opposite sides of a plane extending longitudinally through the overlapping intersection of the chambers;
  
  meshed, lobed rotors rotatably disposed in the chambers, the ends of the rotors and lobes sealingly cooperating with the end wall surfaces, the lobes of each rotor having top lands sealingly cooperating with the cylindrical wall surface of the associated chamber and operative to transverse the port boundaries disposed on the associated side of the plane for effecting transfer of volumes of compressible inlet port fluid to the outlet port via spaces between adjacent unmeshed lobes of each rotor, and the volume of each transfer volume remaining constant while the top lands of the leading and trailing lobes of each transfer volume are disposed between the associated boundaries of the inlet and outlet ports;
  
  the improvement comprising;
  
  a backflow port extending through the housing wall of each cylindrical chamber for effecting a backflow of outlet port fluid into each transfer volume prior to traversal of the outlet port boundaries by the top land of the lead lobe of each transfer volume and after traversal of the inlet port boundaries by the top land of the trailing lobe of each transfer volume, and said backflow ports having a length/width ratio greater than four with the lengthwise extent of said backflow ports being substantially parallel to the lengthwise extent of the traversing top lands to facilitate rapid opening of the backflow ports.

21. A rotary blower of the backflow type including:
- a housing assembly defining two parallel, transversely overlapping cylindrical chambers having internal cylindrical and flat end wall surfaces, the axes of the cylindrical chambers defining a longitudinal direction;
  
  an inlet port and an outlet port having, with respect to the longitudinal direction, longitudinal and transverse boundaries defined by and on opposite sides of the housing assembly, said transverse boundaries of each port being disposed on opposite sides of a plane extending longitudinally through the overlapping intersection of the chambers;
  
  meshed, lobed rotors rotatably disposed in the chambers, the rotor lobes formed with a helical twist, the ends of the rotors and lobes sealingly cooperating with the end wall surfaces, the lobes of each rotor having top lands sealingly cooperating with the cylindrical wall surface of the associated chamber and operative to traverse the port boundaries disposed on the associated side of the plane for effecting transfer of volumes of compressible inlet port fluid to the outlet port via spaces between adjacent unmeshed lobes of each rotor, and the volume of each transfer volume remaining constant while the top lands of the leading and trailing lobes of each transfer volume are disposed between the associated boundaries of the inlet and outlet ports;
  
  the improvement comprising;
  
  a backflow port extending through the housing wall of each cylindrical chamber for effecting a backflow of outlet port fluid into each transfer volume prior to traversal of the outlet port boundaries by the top land of the lead lobe of each transfer volume and after traversal of the inlet port boundaries by the top land of the trailing lobe of each transfer volume, and said backflow port having a length/width ratio greater than four with the lengthwise extent of said backflow ports being substantially parallel to the lengthwise extent of the traversing top lands to facilitate rapid opening of the backflow ports.
- View Dependent Claims (22, 23)
- - 22. The rotary blower of claim 21, wherein the inlet port opening is skewed toward the leading ends of the lobes, the outlet port opening is skewed toward the trailing ends of the lobes, and said backflow ports are skewed toward the leading ends of the lobes.
  - 23. The rotary blower of claim 21, wherein the blower is of the Roots type, each rotor has as least three lobes, the transverse boundaries of the inlet and outlet ports are disposed substantially parallel to the associated lobes when traversed, the top land of the trailing lobe of each transfer volume is in sealing cooperation with its associated cylindrical wall surface for at least 40 rotational degrees before the top land of the leading lobe of each transfer volume traverses the leading edge of the associated backflow port.

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Current Assignee
Eaton Corp. (Wisconsin) (Eaton Corporation PLC.)
Original Assignee
Eaton Corp. (Wisconsin) (Eaton Corporation PLC.)
Inventors
Soeters, Raymond A. Jr.
Primary Examiner(s)
Croyle, Carlton R.
Assistant Examiner(s)
Olds, T. W.

Application Number

US06/799,760
Time in Patent Office

1,023 Days
Field of Search

418/1, 418/15, 418/78, 418/201, 418/206
US Class Current

418/1
CPC Class Codes

F04C 18/16 with helical teeth, e.g. ch...

F04C 29/122 Arrangements for supercharg...

Port arrangement for rotary positive displacement blower

First Claim

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23 Claims

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Port arrangement for rotary positive displacement blower

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Abstract

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23 Claims

Specification

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