CN202326201U

CN202326201U - Spring compensating five-space rotor pump

Info

Publication number: CN202326201U
Application number: CN2011203882299U
Authority: CN
Inventors: 张意立
Original assignee: Individual
Current assignee: Individual
Priority date: 2011-09-30
Filing date: 2011-09-30
Publication date: 2012-07-11
Anticipated expiration: 2021-09-30

Abstract

The utility model relates to a spring compensating five-space rotor pump which comprises a pump body, a rotor shaft and a slave rotor, wherein the rotor shaft is installed on a central through hole of the pump body; and the slave rotor is installed on an eccentric half hole of the pump body. An eccentric end cover is arranged on the outer end surface of the eccentric half hole and fixedly sealed by at least three bolts; the outer end surface of the slave rotor is close to the front plane of a compensating plate; a positioning pin and a pagoda-shaped spring are arranged between the back surface of the compensating plate and the eccentric end cover; the eccentric distance t is from a central axis of the rotor shaft to a central axis of the slave rotor; five contact points are synchronously generated between five equal arc surface working sections of the rotor shaft and six equal arc surfaces of the slave rotor and form five axially-extending sealing belts; five dynamic spaces, i.e. A, B, C, D and E are formed in combination with the bottom surface of the eccentric half hole and the front plane of the compensating plate; and by means of supporting bounce generated by the pagoda-shaped spring supported on a boss on the inner side of the eccentric end cover and used for supporting the compensating plate, the end surface sliding of the five dynamic spaces are always in an effective sealing state.

Description

A kind of spring compensates five Space Rotor pumps

Technical field

The utility model belongs to mechanical engineering field, relate to a kind of with mechanical energy convert into fluid pressure can the transformation of energy displacement pump, be meant that especially a kind of spring compensates five Space Rotor pumps.

Background technique

Known displacement pump main structure form has: plunger pump, screw pump, Roots pump and sliding vane pump.Have the high advantage of efficient as displacement pump, but all exist its efficient of long-time running wearing and tearing back obviously to reduce, cause the main cause of above-mentioned defective to be that movable isolation of end face between hyperbaric chamber and the low pressure chamber fail to play effective sealing.The undersized easy heat expansion of end face fit tolerance is stuck firmly; The end face fit tolerance is oversize then fails to play effective sealing; And long-time running wearing and tearing back sealing effect is poorer, and the production line of having to stop is changed pumping unit, causes very big direct waste and indirect loss.

Summary of the invention

The purpose of the utility model provides a kind of spring and compensates five Space Rotor pumps; The technology that possesses end wear sealing compensation and gauge wear sealing compensation simultaneously; To realize being in good movable isolating seal state for a long time between hyperbaric chamber and the low pressure chamber; Remedy the deficiency of existing technology, fill up the technological gap that displacement pump possesses end wear sealing compensation and gauge wear sealing compensation simultaneously.

To achieve these goals; The utility model provides following technological scheme: a kind of spring compensates five Space Rotor pumps; Comprise the pump housing and be installed on rotor shaft and off-centre half hole that is installed in the pump housing on the central through bore of the pump housing from rotor; Eccentric half outer end of hole face has eccentric end cap next airtight fixing with at least three screw; Pasting the horizontal frontal plane of compensating disc from the exterior edge face of rotor, locating stud and pagoda shape spring are arranged between the back side of compensating disc and the eccentric end cap, described rotor shaft comprises five five equilibrium cambered surface active sections and does not have the keyway shaft part and the shaft with keyway section; The inner end of five five equilibrium cambered surface active sections is pasting bottom surface, eccentric half hole, and the exterior edge face of five five equilibrium cambered surface active sections is being pasted by the horizontal frontal plane of compensating disc; Describedly comprise complete section of six five equilibrium cambered surfaces, the size equal uniform of the width of full section both ends of the surface and the both ends of the surface width of five five equilibrium cambered surface active sections from rotor; Be with " O " type ring recess in the central through bore on the described pump housing; Has eccentric distance t between the central axis in the central axis of central through bore and eccentric half hole; A crescent shape suction inlet UNICOM on the bottom surface, eccentric half hole import, and another crescent shape row mouthful UNICOM outlet; The central axis of described rotor shaft and have eccentric distance t between the centre of rotor axis; Five five equilibrium cambered surface active sections of rotor shaft and from five point of contact of synchronized generation between six five equilibrium cambered surfaces of rotor; Cross point of contact and form five axially extended sealing strips; In conjunction with the horizontal frontal plane of eccentric bottom surface, half hole and compensating disc, constitute A, B, C, D and five dynamic spaces of E; Has eccentric distance t between the central axis of the central axis of the band on the described compensating disc " O " type ring recess through hole and band " O " type ring recess cylindrical; The outer ring that can hold pagoda shape spring in the back side re-entrant angle of compensating disc; The inner ring of pagoda shape spring is enclosed within on the inboard boss of eccentric end cap, and the eccentric positioning hole and the locating stud of compensating disc are slidingly matched.

The beneficial effect of the utility model is: the support rebounding force that is supported on the inboard boss of eccentric end cap by means of pagoda shape spring and is asking the back side of compensating disc to produce; The horizontal frontal plane of compensating disc is close to the exterior edge face of two rotors all the time; Then force the inner end of two rotors also to be close to bottom surface, eccentric half hole, guarantee that the end face slip of five dynamic spaces is in effective sealing all the time.

Rotor shaft and from five axially extended sealing strips of rotor synchronized generation, by means of the support rebounding force of pagoda shape spring, horizontal frontal plane one side of compensating disc is close to the exterior edge face of two rotors all the time, forces the inner end of two rotors also to be close to bottom surface, eccentric half hole then.Constitute A, B, C, D and five dynamic spaces of E and possessed end wear sealing compensation and gauge wear sealing compensation simultaneously, realize being in good movable isolating seal state for a long time between hyperbaric chamber and the low pressure chamber.

Possess in the time of end wear sealing compensation and gauge wear sealing compensation, realize being in good movable isolating seal state for a long time between hyperbaric chamber and the low pressure chamber.

Description of drawings

Fig. 1 is the sectional drawing of the utility model integral body through axis;

Fig. 2 is the sectional drawing in W-W cross section among Fig. 1;

Fig. 3 is an inner rotor shaft 1 and the relative position relation of five dynamic spaces of synchronized generation that are in operation from rotor 2;

Fig. 4 is with respect to Fig. 3, and rotor shaft 1 is around central axis O ₂Be rotated counterclockwise 60 the degree, from rotor 2 around eccentric axis O ₁Be rotated counterclockwise 50 the degree after relative position relation;

Fig. 5 is with respect to Fig. 3, and rotor shaft 1 is around central axis O ₂Be rotated counterclockwise 120 the degree, from rotor 2 around eccentric axis O ₁Be rotated counterclockwise 100 the degree after relative position relation;

Fig. 6 is with respect to Fig. 3, and rotor shaft 1 is around central axis O ₂Be rotated counterclockwise 180 the degree, from rotor 2 around eccentric axis O ₁Be rotated counterclockwise 150 the degree after relative position relation;

Fig. 7 is with respect to Fig. 3, and rotor shaft 1 is around central axis O ₂Be rotated counterclockwise 240 the degree, from rotor 2 around eccentric axis O ₁Be rotated counterclockwise 200 the degree after relative position relation;

Fig. 8 is with respect to Fig. 3, and rotor shaft 1 is around central axis O ₂Be rotated counterclockwise 300 the degree, from rotor 2 around eccentric axis O ₁Be rotated counterclockwise 250 the degree after relative position relation;

Fig. 9 is the outside three-dimensional structure diagram of rotor shaft 1.

Figure 10 is a rotor shaft 1 and from the camberline construction drawing of rotor 2.

Embodiment

In conjunction with accompanying drawing and embodiment, further structure and the working principle to the utility model elaborates.

A kind of spring compensates five Space Rotor pumps; Comprise the pump housing 4 and be installed on rotor shaft 1 and off-centre half hole 42 that is installed in the pump housing 4 on the central through bore 41 of the pump housing 4 from rotor 2; 42 exterior edge faces, eccentric half hole have the screw 8 of at least three of eccentric end cap 5 usefulness airtight fixing; Pasting the horizontal frontal plane of compensating disc 6 from the exterior edge face of rotor 2; Locating stud 7 and pagoda shape spring 9 are arranged between the back side of compensating disc 6 and the eccentric end cap 5; Described rotor shaft 1 comprises five five equilibrium cambered surface active sections 13 and does not have keyway shaft part 11 and exterior edge face that the inner end of 12, five five equilibrium cambered surfaces of shaft with keyway section active section 13 is pasting bottom surface, eccentric half hole 40, five five equilibrium cambered surfaces active section 13 is being pasted by the horizontal frontal plane of compensating disc 6; Describedly comprise complete section of six five equilibrium cambered surfaces, the size equal uniform of the width of full section both ends of the surface and the both ends of the surface width of five five equilibrium cambered surface active sections 13 from rotor 2; Central through bore on the described pump housing 4 is with " O " type ring recess for 41 li; Has eccentric distance t between the central axis in the central axis of central through bore 41 and eccentric half hole 42; Crescent shape suction inlet 47 UNICOMs on the bottom surface, eccentric half hole 40 import 46, and another crescent shape row mouthful 48 UNICOMs outlet 49; The central axis of described rotor shaft 1 and have eccentric distance t between the central axis of rotor 2; Five five equilibrium cambered surface active sections of rotor shaft 1 and from five point of contact of synchronized generation between six five equilibrium cambered surfaces of rotor 2; Cross point of contact and form five axially extended sealing strips; Horizontal frontal plane in conjunction with bottom surface, eccentric half hole 40 and compensating disc 6 constitutes A, B, C, D and five dynamic spaces of E; Has eccentric distance t between the central axis of band " O " the type ring recess through hole 61 on the described compensating disc 6 and the central axis of band " O " type ring recess cylindrical 62; The outer ring that can hold pagoda shape spring 9 in the back side re-entrant angle of compensating disc 6; The inner ring of pagoda shape spring 9 is enclosed within on the inboard boss of eccentric end cap 5, and the eccentric positioning hole 67 and the locating stud 7 of compensating disc 6 are slidingly matched.

" O " type circle in all " O " type ring recess plays the motive sealing effect at position of living in.

Installation steps and working principle:

The shaft with keyway section 12 of rotor shaft 1 is 40 1 sides from bottom surface, off-centre half hole, pass central through bore 41 and are slidingly matched with it, and the inner end of five five equilibrium cambered surface active sections 13 is pasting bottom surface, eccentric half hole 40.Be placed in eccentric half hole 42 from rotor 2 and be slidingly matched, also pasting bottom surface, eccentric half hole 40 from the inner end of rotor 2.Make the central axis O of rotor shaft 1 ₂With eccentric axis O from rotor 2 ₁Between have eccentric distance t; Five five equilibrium cambered surface active sections 13 of rotor shaft 1 and from five point of contact of synchronized generation between six five equilibrium cambered surfaces of rotor 2; Cross point of contact and form five axially extended sealing strips; Horizontal frontal plane in conjunction with bottom surface, eccentric half hole 40 and compensating disc 6 constitutes A, B, C, D and five dynamic spaces of E.Even can guarantee that still five axially extended sealing strips form synchronously after using uniform wear for a long time, guarantee the radially effectively sealing all the time of five dynamic spaces;

The central axis O of the band on the compensating disc 6 " O " type ring recess through hole 61 ₂Eccentric axis O with band " O " type ring recess cylindrical 62 ₁Between have eccentric distance t, can hold the outer ring of pagoda shape spring 9 in the back side re-entrant angle of compensating disc 6, the eccentric positioning hole of compensating disc 6 67 is slidingly matched with locating stud 7.The horizontal frontal plane of compensating disc 6 inwardly, band " O " type ring recess through hole 61 is inserted in from no keyway shaft part 11 1 ends of rotor shaft 1 and is slidingly matched, band " O " type ring recess cylindrical 62 is slidingly matched with eccentric half hole 42.

Locating stud 7 is fastened on the eccentric end cap 5 inboard faces, and the inner ring of pagoda shape spring 9 is enclosed within on the inboard boss of eccentric end cap 5, and band " O " the type ring recess through hole 51 on the eccentric end cap 5 is inserted in from no keyway shaft part 11 1 ends of rotor shaft 1 and is slidingly matched.At least three screw 8 along the outer circular edge of eccentric end cap 5, on the outside end face with airtight off-centre half hole 42 that is fixed on the pump housing 4 of eccentric end cap 5 shimmings 54.

The back side of compensating disc 6 has positioning hole 67 and locating stud 7 to be slidingly matched, and locating stud 7 is fixedly connected with eccentric end cap 5, thereby compensating disc 6 can only be made axial slip with respect to eccentric end cap 5." O " type circle in all " O " type ring recess plays the motive sealing effect at position of living in.

During work; External force drives rotor shaft 1 rotation through shaft with keyway section 12; Then stirring from rotor 2 rotation, is eccentric distance t from both rotating center deviation distances of rotor 2 and rotor shaft 1, five five equilibrium cambered surface active sections 13 of rotor shaft 1 and from five axially extended sealing strips of synchronized generation between six five equilibrium cambered surfaces of rotor 2; Horizontal frontal plane in conjunction with bottom surface, eccentric half hole 40 and compensating disc 6 constitutes A, B, C, D and five dynamic spaces of E.During rotation, A, B, C, D and five dynamic spaces of E along with rotation will become a big side gradually and be crescent shape suction inlet 47, lead to import 46; One side that will diminish gradually along with rotation of A, B, C, D and five dynamic spaces of E is a crescent shape row mouth 48, leads to outlet 49.Rotor shaft 1 continuously rotation order about A, B, C, D and five dynamic spaces of E go round and begin again accomplish inhale, row's work.

Figure 10 is an explanation rotor shaft 1 and from the camberline working process of rotor 2:

Setting-out X of elder generation and vertical with it line Y1 and line Y2, intersection point is respectively O ₁, O ₂, O ₁With O ₂Be 6mm at a distance of get the t distance here for eccentric distance t.;

With O ₁Be the center of circle, R1 is that radius is made basic circle R1.Here getting the R1 radius is 106.0mm;

An intersection point with basic circle R1 and line X is the center of circle, and R2 is that radius is made arc section R2, again with O ₁Be the center of circle, with arc section R2 around O ₁Six five equilibriums annular display.Here getting the R2 radius is 55.8mm;

The distance that is extended to R3 with the intersection point of arc section R2 and line X is the center of circle, is that the intersection point that radius is crossed arc section R2 and line X is made arc section R3 with R3, again with O ₂Be the center of circle, with arc section R3 around O ₂Five five equilibriums annular display.Here getting the R3 radius is 147.5mm;

Choose two arc section R3 and an arc section R2 respectively, the tangent arc section R4 that does of five lines gets the R4 radius here and is approximately 7.4mm;

With R5 is that radius is made two adjacent arc section R2 of arc section R5 connection respectively, and the R5 radius is 68.3mm here.

Article five, arc section R4 alternately with five point of contact of six arc section R2 synchronized generation, cross point of contact and form five axially extended sealing strips, constitute A, B, C, D and five dynamic spaces of E.Even after using uniform wear for a long time, five point of contact of synchronized generation form five axially extended sealing strips can guarantee that still five axially extended sealing strips form synchronously, and that guarantees five dynamic spaces radially is in effective sealing all the time.

The both ends of the surface width of five five equilibrium cambered surface active sections 13 of rotor shaft 1 and size equal uniform from the both ends of the surface width of rotor 2; Here getting the both ends of the surface width all is 70.0mm; The inner end of two rotors is all pasting bottom surface, eccentric half hole 40, and the horizontal frontal plane of compensating disc 6 is pasting the exterior edge face of two rotors simultaneously.The support rebounding force that is supported on the inboard boss of eccentric end cap 5 by means of pagoda shape spring 9 and is asking the back side of compensating disc 6 to produce; The horizontal frontal plane of compensating disc 6 is close to the exterior edge face of two rotors all the time; Then force the inner end of two rotors also to be close to bottom surface, eccentric half hole 40, guarantee that the end face slip of five dynamic spaces is in effective sealing all the time.

Claims

1. a spring compensates five Space Rotor pumps; Comprise the pump housing (4) and be installed in the rotor shaft (1) on the central through bore (41) of the pump housing (4) and be installed on off-centre half hole (42) of the pump housing (4) from rotor (2); Exterior edge face, eccentric half hole (42) has eccentric end cap (5) next airtight fixing with at least three screw (8); Pasting the horizontal frontal plane of compensating disc (6) from the exterior edge face of rotor (2); Locating stud (7) and pagoda shape spring (9) are arranged between the back side of compensating disc (6) and the eccentric end cap (5); It is characterized in that: described rotor shaft (1) comprises five five equilibrium cambered surface active sections (13) and do not have keyway shaft part (11) and shaft with keyway section (12), and the inner end of five five equilibrium cambered surface active sections (13) is pasting bottom surface, eccentric half hole (40), and the exterior edge face of five five equilibrium cambered surface active sections (13) is being pasted by the horizontal frontal plane of compensating disc (6); Describedly comprise complete section of six five equilibrium cambered surfaces, the size equal uniform of the width of full section both ends of the surface and the both ends of the surface width of five five equilibrium cambered surface active sections (13) from rotor (2); " O " type ring recess is with in central through bore (41) lining on the described pump housing (4); Has eccentric distance t between the central axis in the central axis of central through bore (41) and eccentric half hole (42); Crescent shape suction inlet (47) UNICOM on the eccentric bottom surface, half hole (40) import (46), and another crescent shape row mouthful (48) UNICOM outlet (49); The central axis of described rotor shaft (1) and have eccentric distance t between the central axis of rotor (2); Five five equilibrium cambered surface active sections of rotor shaft (1) and from five point of contact of synchronized generation between six five equilibrium cambered surfaces of rotor (2); Cross point of contact and form five axially extended sealing strips; In conjunction with the horizontal frontal plane of bottom surface, eccentric half hole (40) and compensating disc (6), constitute A, B, C, D and five dynamic spaces of E; Has eccentric distance t between the central axis of band " O " the type ring recess through hole (61) on the described compensating disc (6) and the central axis of band " O " type ring recess cylindrical (62); The outer ring that can hold pagoda shape spring (9) in the back side re-entrant angle of compensating disc (6); The inner ring of pagoda shape spring (9) is enclosed within on the inboard boss of eccentric end cap (5), and the eccentric positioning hole (67) of compensating disc (6) is slidingly matched with locating stud (7).