CN204877885U - Balance wheel structure improvement of diaphragm booster pump - Google Patents

Abstract

The utility model relates to a balance wheel structure improvement of diaphragm booster pump, it fixes a position ring grooves to establish to the region of perpendicular side face and possess into downward inclined plane on each the cylinder balance normal water flat top face with balance seat in the pump body, it fixes a position the downward inclined plane of ring grooves to perpendicular side face on this cylinder balance normal water flat top face of measured time to make unfamiliar booster pump do, complete smooth support simultaneously is on the diaphragm bottom surface of drawing the state to one side, and can not produce the disappearance that "extrudeed" to this diaphragm bottom surface, remove and to improve the diaphragm by a wide margin and bear cylinder balance high -frequency top and push away enduring of effect and be outside one's consideration, more can prolong the life of whole unfamiliar booster pump.

Description

The swing wheel structure improvement of diaphragm booster pump

Technical field

The utility model is relevant with the diaphragm booster pump be installed in reverse osmosis water filter (reverseosmosispurification), when referring to that one can eliminate known diaphragm booster pump start especially, its cylinder escapement end face rounding produces to diaphragm bottom surface the swing wheel structure improvement that 〝 extrudes 〞 disappearance, and has and significantly improve diaphragm and bear the tolerance level of cylinder escapement high frequency thrusting action and extend working life of diaphragm booster pump.

Background technique

Knownly at present be used in the special diaphragm booster pump of reverse osmosis water filter, by exposure such as No. the 4396357th, 4610605,5476367,5571000,5615597,5649812,5706715,5791882 and 5816133, U. S. Patent etc. be all, its structure as shown in Figures 1 to 10, is combined by motor 10, motor protecgulum 30, inclination eccentric cam 40, escapement seat 50, pump head seat 60, diaphragm 70, three piston thrust block 80, piston valve body 90 and a pump head lid 20, wherein, the central build-in of motor protecgulum 30 has a bearing 31, is placed by the force-output shaft 11 of motor 10, and its outer periphery are convexly equipped with a circle epirelief annulus 32, and on the inner edge surface of this epirelief annulus 32, be provided with several fixing perforation 33, these inclination eccentric cam 40 central authorities run through an axis hole 41, can for being placed on the force-output shaft 11 of motor 10, the pedestal bottom center build-in of this escapement seat 50 has an escapement bearing 51, can be nested with on inclination eccentric cam 40, the end face equi-spaced apart arrangement of its pedestal is convexly equipped with three cylinder escapements 52, the horizontal top surface 53 of each cylinder escapement 52 is arranged with a tapped hole 54, and be arranged with a delineation position concave ring groove 55 again in the periphery of this tapped hole 54, and its horizontal top surface 53 becomes rounding 57 with vertical side edge face 56 place of connecting setting tool, this pump head seat 60 is that cover is placed on the epirelief annulus 32 of motor protecgulum 30, its end face is equipped with three equi-spaced apart and is greater than the start perforation 61 of three cylinder escapement 52 external diameters in escapement seat 50, make three cylinder escapements 52 can be placed through in three start perforation 61, its bottom surface is to having dome ring 62 under a circle again, the yardstick of this lower dome ring 62 is identical with epirelief annulus 32 yardstick of motor protecgulum 30, another end face down dome ring 62 direction near outer periphery, then be equipped with several fixing perforation 63, this diaphragm 70 is placed on the end face of pump head seat 60, by semi-rigid elastic material ejection formation, its outermost periphery end face is equipped with two circles and parallels opposed outer raised line 71 and interior raised line 72, and give off three roads and this interior raised line 72 phase fin 73 in succession by end face central position, between Shi Gai tri-road fin 73 and interior raised line 72, three piston start districts 74 have been separated out between quilt, and each piston start district 74 corresponds on tapped hole 54 position of each cylinder escapement 52 horizontal top surface 53 in escapement seat 50, respectively be equipped with again a central perforation 75, and be convexly equipped with a circle positioning convex ring block 76 (as can be seen from figures 8 and 9) in diaphragm 70 bottom surface being positioned at each central perforation 75, this three piston thrust block 80 is placed in three piston start districts 74 of diaphragm 70 respectively, each piston thrust block 80 runs through and is provided with a shoulder hole 81, three positioning convex ring blocks 76 of diaphragm 70 bottom surface are plugged in the location concave ring groove 55 of three cylinder escapements 52 in escapement seat 50 respectively, the shoulder hole 81 into piston thrust block 80 is worn again with retaining screw 1, and after passing the central perforation 75 in three piston start districts 74 in diaphragm 70, diaphragm 70 and three piston thrust blocks 80 can be fixed at simultaneously the tapped hole 54 interior (as shown in the zoomed-in view in Figure 10) of three cylindrical escapement 52 in escapement seat 50, the bottom outer peripheral edge side of this piston valve body 90 is convexly equipped with a ring raised line 91 downwards, the space between diaphragm 70 China and foreign countries' raised line 71 and interior raised line 72 can be plugged, its middle position towards pump head lid 20 direction is provided with the circular drainage seat 92 that an end face has concave arc surface, and be equipped with a positioning hole 93 in the central authorities of drainage seat 92, can penetrate fixing for a T-shaped non-return rubber cushion 94, on the region of the another 120 degree of angular position in each interval centered by this positioning hole 93, respectively be equipped with several weep hole 95, and to should in drainage seat 92 peripheral surface in three area sewerage holes 95, be equipped with again spaced 120 degree of angles arrangement respectively and opening three influent bases 96 all down, each influent base 96 is equipped with again several water inlet 97, and place the T-shaped piston sheet of a handstand 98 in the central authorities of each influent base 96, can hinder by this piston sheet 98 and cover each water inlet 97, wherein, weep hole 95 in drainage seat 92 on each region, each influent base 96 is corresponding thereto connected respectively, after ring raised line 91 bottom piston valve body 90 is plugged the space between the outer raised line 71 of diaphragm 70 and interior raised line 72, can between each influent base 96 and end face of diaphragm 70, respectively be formed with a pressurized chamber 26 (as shown in Figure 10 and zoomed-in view thereof) closed, this pump head lid 20 is covered on pump head seat 60, its outer edge surface is provided with a water intake 21, one water outlet 22 and several fixing perforation 23, and be provided with a scalariform groove 24 in the bottom part ring of inner edge surface, assemblying body outer rim after diaphragm 70 and piston valve body 90 are coincided mutually, can be closely attached to (as shown in the zoomed-in view in Figure 10) on this scalariform groove 24, another edge face central authorities are within it provided with a circle dome ring 25, the bottom of this dome ring 25 presses on the outer edge surface of drainage seat 92 in piston valve body 90, make between the internal face of this dome ring 25 and the drainage seat 92 of piston valve body 90, can around formation one high pressure hydroecium 27 (as shown in Figure 10), the each fixing perforation 23 of pump head lid 20 is each passed through by fixing bolt 2, and by after each fixing perforation 63 of pump head seat 60, be screwed with the nut 3 of inserting in pump head seat 60 in each fixing perforation 63 respectively again, and to be directly screwed in motor protecgulum 30 in each fixing perforation 33, the combination (as shown in Fig. 1 and Figure 10) of whole diaphragm booster pump can be completed.

As shown in FIG. 11 and 12, be above-mentioned known diaphragm booster pump make flowing mode, after the force-output shaft 11 of motor 10 rotates, inclination eccentric cam 40 can be driven to rotate, and make on escapement seat 50 three cylinder escapements 52 sequentially produce in upper and lower reciprocal start simultaneously, and three piston start districts 74 on diaphragm 70, also the start up and down of three cylinder escapements 52 can be subject to, synchronous sequentially by up pushing tow and toward drop-down and upper and lower displacement that is that produce repeatedly, therefore, when cylinder escapement 52 down start time, synchronously by the piston start district 74 of diaphragm 70 and piston thrust block 80 toward drop-down, the piston sheet 98 of piston valve body 90 is pushed open, and in the future the tap water W of self-pumping skull 20 water intake 21 via water inlet 97, and enter in pressurized chamber 26 (as shown in the arrow W in Figure 11 and zoomed-in view thereof), when cylinder escapement 52 up pushing tow start time, also synchronous each piston start district 74 of diaphragm 70 and piston thrust block 80 up to be pushed up, and the water in pressurized chamber 26 is extruded, its hydraulic pressure is made to be increased between 80psi ~ 100psi, non-return rubber cushion 94 on drainage seat 92 can be pushed open by the high pressure water Wp therefore after boosting, and via each weep hole 95 of drainage seat 92, sequentially constantly flow in high pressure hydroecium 27, and then discharge diaphragm booster pump outer (as shown in the arrow Wp in Figure 12 and zoomed-in view thereof) via the water outlet 22 of pump head lid 20, and then provide RO film pipe in reverse osmosis water filter to carry out the water pressure needed for osmosis filtration.

As shown in FIG. 13 and 14, during above-mentioned known diaphragm booster pump start, three cylinder escapements 52 are subject to the pushing tow of inclination eccentric cam 40 rotation, also each piston start district 74 of pushing tow diaphragm 70 can be flowed to by connecting traction wheel, it equals on the position, three piston start districts 74 of diaphragm 70 bottom surface, constantly impose a directed force F upwards, and diaphragm 70 bottom surface be applied at every turn power F upwards pushing tow time, also downward reaction force Fs can synchronously be produced, the size distribution of its power act on be arranged in each piston start district 74 diaphragm 70 on (shown in the distribution arrow of size reaction force Fs as each in Figure 14), make diaphragm 70 bottom surface be positioned on position, three piston start districts 74 can produce the phenomenon be extruded simultaneously, wherein, again to be arranged in the diaphragm 70 basal surface position P that cylinder escapement 52 horizontal top surface 53 contacts with intersection place of rounding 57 phase, the extruding degree that it is subject to is maximum (as shown in figure 14), therefore, at force-output shaft 11 rotating speed of motor 10 up under 700-1200rpm, in this diaphragm 70, the basal surface position P in each piston start district 74 meeting at least per second is subject to the extruding of more than 4 times, and under being in high-frequency extrusion passes like this, namely the basal surface position P of this diaphragm 70 is caused to produce the position of breaking the earliest, and also cause whole diaphragm booster pump cannot normal start and the main cause that reduces its working life again, therefore how to exempt the bottom surface in diaphragm 70 piston start district 74, because being subject to the cylinder escapement 52 high frequency pushing tow extruding crackly disappearance that causes, be become a problem urgently anxious to be resolved.

Summary of the invention

Main purpose of the present utility model improves providing a kind of swing wheel structure of diaphragm booster pump, it becomes horizontal top surface in each cylinder escapement in escapement seat being located the region setting tool of concave ring groove to vertical side edge face to lower inclined plane, after making the motor force-output shaft of diaphragm booster pump rotate start, three cylinder escapements are subject to inclination eccentric cam when rotating the diaphragm bottom surface in up pushing tow piston start district, its active force upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm between positioning convex ring to outer raised line can be made, by horizontal top surface in each cylinder escapement is located concave ring groove to vertical side edge face to lower inclined plane, can simultaneously completely smoothly be supported on the bottom surface, diaphragm piston start district of this oblique pull state, and can not produce to bottom surface, diaphragm piston start district the phenomenon that 〝 extrudes 〞, therefore the rounding of cylinder escapement in known diaphragm booster pump can be eliminated completely, to the diaphragm piston start district bottom surface high frequency extruding crackly disappearance that causes, and then significantly can improve the tolerance level that diaphragm bears cylinder escapement high frequency thrusting action, and effectively extend the working life of whole diaphragm booster pump.

Another object of the present utility model improves providing a kind of swing wheel structure of diaphragm booster pump, it becomes horizontal top surface in each cylinder escapement in escapement seat being located the region setting tool of concave ring groove to vertical side edge face to lower inclined plane, after making the motor force-output shaft of diaphragm booster pump rotate start, three cylinder escapements are subject to inclination eccentric cam when rotating the diaphragm bottom surface in up pushing tow piston start district, its active force upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm between positioning convex ring to outer raised line can be made, by horizontal top surface in each cylinder escapement is located concave ring groove to vertical side edge face to lower inclined plane, can simultaneously completely smoothly be supported on the diaphragm bottom surface of this oblique pull state, and can not produce to bottom surface, diaphragm piston start district the phenomenon that 〝 extrudes 〞, diaphragm is made to be subject to upwards after active force, its reaction force synchronously produced significantly reduces, therefore effectively can reduce operating current load and the operating temperature of motor, and then to the lubricant oil in motor bearing can not cause high temperature evaporate to dryness cause lubricating the disappearance of the different sound of not good generation, except all bearings normal operations can guaranteed in diaphragm booster pump are smooth-going, the expenditure of the electric power electricity charge is more reduced because motor operations electric current reduces, have the multiple benefits such as the working life extending whole diaphragm booster pump concurrently simultaneously.

The technical solution of the utility model is: a kind of swing wheel structure improvement of diaphragm booster pump, comprising: a motor, one motor protecgulum, its central build-in has a bearing, and is placed by the force-output shaft of motor, is convexly equipped with a circle epirelief annulus, and on the inner edge surface of this epirelief annulus, is provided with several fixing perforation in outer periphery, one inclination eccentric cam, its central authorities run through an axis hole, and cover is fixed on the force-output shaft of motor, one escapement seat, its bottom center build-in has an escapement bearing, and be nested with on inclination eccentric cam, the end face equi-spaced apart arrangement of its pedestal is convexly equipped with three cylinder escapements, the horizontal top surface of each cylinder escapement is arranged with a tapped hole, and is arranged with a delineation circle of position ring groove again in the periphery of this tapped hole, one pump head seat, that cover is placed on the epirelief annulus of motor protecgulum, its end face is equipped with three equi-spaced apart and is greater than the start perforation of three cylinder escapement external diameters in escapement seat, make three cylinder escapements can be placed through in three start perforation, its bottom surface is to having dome ring under a circle again, the yardstick of this lower dome ring is identical with the epirelief annulus yardstick of motor protecgulum, the another end face down convex annular direction near outer periphery, then is equipped with several fixing perforation, one diaphragm, be placed on the end face of pump head seat, by semi-rigid elastic material ejection formation, its outermost periphery end face is equipped with two circles and parallels opposed outer raised line and interior raised line, and give off three roads by end face central position and to connect with this interior raised line the fin connected, between Shi Gai tri-road fin and interior raised line, three piston start districts have been separated out between quilt, and each piston start district corresponds on the tapped hole position of each cylinder escapement end face in escapement seat, respectively be equipped with a central perforation again, and be convexly equipped with a circle positioning convex ring block in the diaphragm bottom surface being positioned at each central perforation, three piston thrust blocks, be placed in three piston start districts of diaphragm respectively, each piston thrust block runs through and is provided with a shoulder hole, three of diaphragm bottom surface positioning convex ring blocks are plugged in the location concave ring groove of three cylinder escapements in escapement seat respectively, the shoulder hole into piston thrust block is worn again with retaining screw, and after passing the central perforation in three piston start districts in diaphragm, can diaphragm and three piston thrust blocks be fixed in the tapped hole of three cylindrical escapement in escapement seat simultaneously, one piston valve body, be placed on diaphragm, its bottom outer peripheral edge side is convexly equipped with a ring raised line downwards, the space between diaphragm China and foreign countries' raised line and interior raised line can be plugged, the circular drainage seat that an end face has concave arc surface is being provided with towards the middle position in pump head lid direction, and be equipped with a positioning hole in the central authorities of drainage seat, can penetrate fixing for a T-shaped non-return rubber cushion, on the region of the another 120 degree of angular position in each interval centered by this positioning hole, respectively be equipped with several weep hole, and to should in the drainage seat peripheral surface in three area sewerage holes, be equipped with again spaced 120 degree of angles arrangement respectively and opening three influent bases all down, each influent base is equipped with again several water inlet, and place the T-shaped piston sheet of a handstand in the central authorities of each influent base, and a pump head lid, be covered on pump head seat, and by diaphragm and piston valve body coated, its outer edge surface is provided with a water intake, a water outlet and several fixing perforation, a scalariform groove is provided with in the bottom part ring of inner edge surface, assemblying body outer rim after diaphragm and piston valve body can being coincided mutually, is closely attached on this scalariform groove, and separately within it edge face central authorities are provided with a circle dome ring, in each cylinder escapement of this escapement seat, horizontal top surface is located the region setting tool one-tenth of concave ring groove to vertical side edge face to lower inclined plane.

When concrete enforcement, this motor can be have carbon brush motor, and this motor also can be non-carbonate motor.

The beneficial effects of the utility model are: provide a kind of swing wheel structure of diaphragm booster pump to improve, it becomes horizontal top surface in each cylinder escapement in escapement seat being located the region setting tool of concave ring groove to vertical side edge face to lower inclined plane, after making the motor force-output shaft of diaphragm booster pump rotate start, three cylinder escapements are subject to inclination eccentric cam when rotating the diaphragm bottom surface in up pushing tow piston start district, its active force upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm between positioning convex ring to outer raised line can be made, by horizontal top surface in each cylinder escapement is located concave ring groove to vertical side edge face to lower inclined plane, can simultaneously completely smoothly be supported on the bottom surface, diaphragm piston start district of this oblique pull state, and can not produce to bottom surface, diaphragm piston start district the phenomenon that 〝 extrudes 〞, therefore the rounding of cylinder escapement in known diaphragm booster pump can be eliminated completely, to the diaphragm piston start district bottom surface high frequency extruding crackly disappearance that causes, and then significantly can improve the tolerance level that diaphragm bears cylinder escapement high frequency thrusting action, and effectively extend the working life of whole diaphragm booster pump.

In addition, swing wheel structure improvement of the present utility model, it becomes horizontal top surface in each cylinder escapement in escapement seat being located the region setting tool of concave ring groove to vertical side edge face to lower inclined plane, after making the motor force-output shaft of diaphragm booster pump rotate start, three cylinder escapements are subject to inclination eccentric cam when rotating the diaphragm bottom surface in up pushing tow piston start district, its active force upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm between positioning convex ring to outer raised line can be made, by horizontal top surface in each cylinder escapement is located concave ring groove to vertical side edge face to lower inclined plane, can simultaneously completely smoothly be supported on the diaphragm bottom surface of this oblique pull state, and can not produce to bottom surface, diaphragm piston start district the phenomenon that 〝 extrudes 〞, diaphragm is made to be subject to upwards after active force, its reaction force synchronously produced significantly reduces, therefore effectively can reduce operating current load and the operating temperature of motor, and then to the lubricant oil in motor bearing can not cause high temperature evaporate to dryness cause lubricating the disappearance of the different sound of not good generation, except all bearings normal operations can guaranteed in diaphragm booster pump are smooth-going, the expenditure of the electric power electricity charge is more reduced because motor operations electric current reduces, have the multiple benefits such as the working life extending whole diaphragm booster pump concurrently simultaneously.

Accompanying drawing explanation

Fig. 1 is the three-dimensional combination figure of known diaphragm booster pump.

Fig. 2 is the three-dimensional exploded view of known diaphragm booster pump.

Fig. 3 is the stereogram of escapement seat in known diaphragm booster pump.

Fig. 4 is the sectional drawing of 4-4 line in Fig. 3.

Fig. 5 is the stereogram of pump head seat in known diaphragm booster pump.

Fig. 6 is the sectional drawing of 6-6 line in Fig. 5.

Fig. 7 is the stereogram of known diaphragm booster pump septation sheet.

Fig. 8 is the sectional drawing of 8-8 line in Fig. 7.

Fig. 9 is the bottom view of known diaphragm booster pump septation sheet.

Figure 10 is the sectional drawing of 10-10 line in Fig. 1.

Figure 11 is one of illustrative view of known diaphragm booster pump.

Figure 12 is the illustrative view two of known diaphragm booster pump.

Figure 13 is the illustrative view three of known diaphragm booster pump.

Figure 14 is the zoomed-in view of view a in Figure 13.

Figure 15 is the three-dimensional exploded view that the utility model first embodiment is installed on known diaphragm booster pump.

Figure 16 is the stereogram of the utility model first embodiment.

Figure 17 is the sectional drawing of 17-17 line in Figure 16.

Figure 18 is the sectional drawing that the utility model first embodiment is installed on known diaphragm booster pump.

Figure 19 is the illustrative view of the utility model first embodiment.

Figure 20 is the zoomed-in view of view a in Figure 19.

Figure 21 is that the utility model first embodiment compares schematic diagram with the section after cylinder escapement in known diaphragm booster pump respectively start pushing tow diaphragm.

Figure 22 is the stereogram of the utility model second embodiment.

Figure 23 is the sectional drawing of 23-23 line in Figure 22.

Figure 24 is the sectional drawing that the utility model second embodiment is installed on known diaphragm booster pump.

Figure 25 is the illustrative view of the utility model second embodiment.

Figure 26 is the zoomed-in view of view a in Figure 25.

Figure 27 is that the utility model second embodiment compares schematic diagram with the section after cylinder escapement in known diaphragm booster pump respectively start pushing tow diaphragm.

Figure 28 is the three-dimensional exploded view of another embodiment of cylinder escapement in the utility model second embodiment.

Figure 29 is the sectional drawing of 29-29 line in Figure 28.

Figure 30 is the three-dimensional combination figure of another embodiment of cylinder escapement in the utility model second embodiment.

Figure 31 is the sectional drawing of 31-31 line in Figure 30.

Figure 32 is the sectional drawing that in the utility model second embodiment, another embodiment of cylinder escapement is installed on known diaphragm booster pump.

Figure 33 is the illustrative view that in the utility model second embodiment, another embodiment of cylinder escapement is installed on known diaphragm booster pump.

Figure 34 is the zoomed-in view of view a in Figure 33.

Figure 35 is that in the utility model second embodiment, another embodiment of cylinder escapement and cylinder escapement in the known diaphragm booster pump section respectively after start pushing tow diaphragm compares schematic diagram.

In figure, concrete label is as follows:

1-retaining screw 2-fixing bolt

10-motor 11-force-output shaft

20-pump head lid 21-water intake

The fixing perforation of 22-water outlet 23,63-

24-scalariform groove 25-dome ring

26-pressurized chamber 27-high pressure hydroecium

30-motor protecgulum 31-bearing

The fixing perforation of 32-epirelief annulus 33-

40-inclination eccentric cam 41-axis hole

50,500-escapement seat 51-escapement bearing

52,502-cylinder escapement 53,503-horizontal top surface

54,514-tapped hole 55,505,515-setting circle ring groove

56-vertical side edge face 57-rounding

58,508,526-is to lower inclined plane 60-pump head seat

Dome ring under 61-start perforation 62-

The outer raised line of 70-diaphragm 71-

Raised line 73-fin in 72-

74-piston start district 75-central perforation

76-annulus projection 80-piston thrust block

81-shoulder hole 90-piston valve body

91-ring raised line 92-drainage seat

The non-return rubber cushion of 93-positioning hole 94-

95-weep hole 96-influent base

97-water inlet 98-piston sheet

506,522-slopes inwardly edge surface 511-cylindrical seat

512-plane of orientation 513-protruding circular column

Hole, rank on 521-escapement annulus 523-

Hole, rank under 524-scala media hole 525-

F-directed force F s-reaction force

P-basal surface position W-tap water

Wp-high pressure water.

Embodiment

As shown in FIG. 15 to 18, for the first embodiment that the swing wheel structure of the utility model diaphragm booster pump is improved, it is that the region setting tool of in each the cylinder escapement 52 by escapement seat 50, horizontal top surface 53 being located concave ring groove 55 to vertical side edge face 56 becomes to lower inclined plane 58.

Continuous as shown in Figure 19 to Figure 21, when the swing wheel structure of above-mentioned the utility model diaphragm booster pump improves first embodiment's start, three cylinder escapements 52 are subject to after inclination eccentric cam 40 rotates diaphragm 70 bottom surface in up pushing tow piston start district 74, its directed force F upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm 70 between positioning convex ring block 76 to outer raised line 71 can be made, by horizontal top surface 53 in this cylinder escapement 52 is located concave ring groove 55 to vertical side edge face 56 to lower inclined plane 58, can simultaneously complete smooth contact be supported on the bottom surface, diaphragm 70 piston start district 74 of this oblique pull state, and can not produce to bottom surface, diaphragm 70 piston start district 74 phenomenon (as shown in FIG. 19 and 20) that 〝 extrudes 〞, and the reaction force Fs that this diaphragm 70 synchronously produces also can significantly reduce (as shown in the arrow distribution of size reaction force Fs each in Figure 20 thereupon, known after it is compared with each size reaction force Fs in Figure 14, the reaction force Fs that certain the utility model can make diaphragm 70 synchronously produce significantly reduces), therefore, by horizontal top surface 53 in the utility model cylinder escapement 52 is located concave ring groove 55 to vertical side edge face 56 to lower inclined plane 58, except the rounding 57 can eliminating cylinder escapement 52 in known diaphragm booster pump completely, 〞 is extruded to diaphragm 70 piston start district 74 bottom surface high frequency 〝 and causes crackly disappearance outer (as shown in imaginary line part in Figure 21), and have and diaphragm 70 is subject to upwards after directed force F, synchronously produce effect that reaction force Fs significantly reduces, make diaphragm 70 significantly can improve the tolerance level bearing cylinder escapement 52 high frequency thrusting action, and effectively can reduce operating current load and the operating temperature of motor, and then to the lubricant oil in motor bearing can not cause high temperature evaporate to dryness cause lubricating the disappearance of the different sound of not good generation, except all bearings normal operations can guaranteed in diaphragm booster pump are smooth-going, the expenditure of the electric power electricity charge is more reduced because motor operations electric current reduces, have the multiple benefits such as the working life extending whole diaphragm booster pump concurrently simultaneously, the utility model is installed on known diaphragm booster pump and shows via the result after actual measurement, the operating temperature of motor 10 can reduce at least 15 DEG C, operating current can reduce more than 1 ampere, and can increase the working life of diaphragm 70 and whole diaphragm booster pump and reach more than twice.

As shown in Figure 22 to Figure 24, for the second embodiment that the swing wheel structure of the utility model diaphragm booster pump is improved, it is by the enlarged diameter of each cylinder escapement 502 in escapement seat 500, but still be less than the internal diameter of start perforation 61 in pump head seat 60, and the edge surface 506 that becomes to slope inwardly by its edge surface setting tool, and in each cylinder escapement 502, horizontal top surface 503 is located the region setting tool one-tenth of concave ring groove 505 to this edge surface 506 that slopes inwardly to lower inclined plane 508.

Continuous as shown in Figure 25 to Figure 27, when the swing wheel structure of above-mentioned the utility model diaphragm booster pump improves second embodiment's start, three cylinder escapements 502 are subject to inclination eccentric cam 40 when rotating diaphragm 70 bottom surface in up pushing tow piston start district 74, its directed force F upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm 70 between positioning convex ring block 76 to outer raised line 71 can be made, by horizontal top surface 503 in this cylinder escapement 502 is located concave ring groove 505 to the edge surface 506 that slopes inwardly to lower inclined plane 508, can simultaneously complete smooth contact be supported on diaphragm 70 bottom surface of this oblique pull state, and can not produce to bottom surface, diaphragm 70 piston start district 74 phenomenon (as shown in Figure 25 and Figure 26) that 〝 extrudes 〞, and the reaction force Fs that this diaphragm 70 synchronously produces also can significantly reduce (as shown in the arrow distribution of size reaction force Fs each in Figure 26) thereupon, and the project organization of the edge surface 506 that slopes inwardly, can because of after cylinder escapement 502 enlarged diameter, its start upwards pushing tow displacement time, can avoid abutting against the wall surface of the hole of start perforation 61 in pump head seat 60, therefore, by horizontal top surface 503 in the utility model cylinder escapement 502 is located concave ring groove 505 to the edge surface 506 that slopes inwardly to lower inclined plane 508, except the disappearance that the piston start district, rounding 57 pairs of diaphragm 70 bottom surfaces 74 can eliminating cylinder escapement 502 in known diaphragm booster pump completely produces 〝 extruding 〞 (as shown in imaginary line part in Figure 27), and have and diaphragm 70 is subject to upwards after directed force F, synchronously produce effect that reaction force Fs significantly reduces, make diaphragm 70 significantly can improve the tolerance level bearing cylinder escapement 502 high frequency thrusting action, and then effectively extend the working life of whole diaphragm booster pump.In addition, due to the enlarged diameter of cylinder escapement 502, also its area to lower inclined plane 508 is made to be strengthened, therefore the area (in as Figure 27 shown in figure number A) of smooth contact oblique pull state diaphragm 70 bottom surface can be increased when start, and the support increased reaction force Fs, and then reduce the influence degree that diaphragm 70 is subject to reaction force Fs again, also to producing the effect extended again the working life of diaphragm 70.

As shown in Figure 28 to Figure 31, the swing wheel structure of above-mentioned the utility model diaphragm booster pump is improved in the second embodiment, this each cylinder escapement 502 changes setting tool and is made up of a cylindrical seat 511 and an escapement annulus 521, wherein, the circumferential outer edge face of cylindrical seat 511 is provided with one plane of orientation 512, and be provided with a protruding circular column 513 end face is convex, and the end face fovea centralis of this protruding circular column 513 is provided with a tapped hole 514, this escapement annulus 521 is nested with on cylindrical seat 511, its outer periphery face is set as the edge surface 522 that slopes inwardly, in end face, central authorities are provided with mutually through hole, upper rank 523 toward direction, bottom surface, scala media hole 524 and hole, lower rank 525, wherein, the aperture in hole, upper rank 523 is greater than the external diameter of protruding circular column 513 in cylindrical seat 511, the internal diameter in scala media hole 524 is identical with the external diameter of protruding circular column 513 in cylindrical seat 511, the internal diameter in hole, lower rank 525 is identical with the external diameter of cylindrical seat 511, separately be set as to lower inclined plane 526 by hole, upper rank 523 to the region of the edge surface 522 that slopes inwardly, escapement annulus 521 is nested with after cylindrical seat 511, one can be formed between protruding circular column 513 and hole, upper rank 523 and locate concave ring groove 515 (as shown in Figure 30 and Figure 31).

Continuous as shown in Figure 32 to Figure 35, after above-mentioned escapement annulus 521 and cylindrical seat 511 phase fit, three positioning convex ring blocks 76 of diaphragm 70 bottom surface are plugged in the location concave ring groove 515 of three cylinder escapements 502 in escapement seat 500 respectively, the shoulder hole 81 into piston thrust block 80 is worn again by retaining screw 1, and after passing the central perforation 75 in three piston start districts 74 in diaphragm 70, diaphragm 70 and three piston thrust blocks 80 can be fixed at simultaneously the tapped hole 514 interior (as shown in the zoomed-in view in Figure 32) of the cylindrical seat 511 of three cylindrical escapement 502 in escapement seat 500, when the force-output shaft 11 of motor 10 rotates, three cylinder escapements 502 are subject to inclination eccentric cam 40 when rotating diaphragm 70 bottom surface in up pushing tow piston start district 74, its directed force F upwards, the barrier film lamellar body generation oblique pull state upwards in diaphragm 70 between positioning convex ring block 76 to outer raised line 71 can be made, by escapement annulus 521 in this cylinder escapement 502 location concave ring groove 515 to the edge surface 522 that slopes inwardly to lower inclined plane 526, can simultaneously complete smooth contact be supported on diaphragm 70 bottom surface of this oblique pull state, and can not produce to diaphragm 70 bottom surface the phenomenon (as shown in Figure 33 and Figure 34) that 〝 extrudes 〞, and the reaction force Fs that this diaphragm 70 synchronously produces also can significantly reduce (as shown in the arrow distribution of size reaction force Fs each in Figure 34) thereupon, and the project organization of the edge surface 522 that slopes inwardly, still can because of after cylinder escapement 502 enlarged diameter, its start upwards pushing tow displacement time, can avoid abutting against the wall surface of the hole of start perforation 61 in pump head seat 60, therefore, it is except the disappearance that rounding 57 pairs of diaphragm 70 bottom surfaces can eliminating cylinder escapement 502 in known diaphragm booster pump completely produce 〝 extruding 〞 (as shown in imaginary line part in Figure 35), still have and diaphragm 70 is subject to upwards after directed force F, synchronously produce effect that reaction force Fs significantly reduces, make diaphragm 70 significantly can improve the tolerance level bearing cylinder escapement 502 high frequency thrusting action, and then effectively extend the working life of whole diaphragm booster pump, and except identical with effect that above-mentioned second embodiment has, this has slope inwardly edge surface 522 and the escapement annulus 521 to lower inclined plane 526, the feasibility of demoulding must be considered when making, therefore itself and escapement seat 500 are separated making, the cost of manufacture can be saved, cylindrical seat 511 then can make in one-body molded mode with escapement seat 500, again both are combined into cylinder escapement 502, therefore, this structural design has completely and meets industry and produce and save the double benefit of overall manufacture cost in a large number.

In sum, the utility model is with the most easy cylinder escapement improvement structure, reach the working life extending diaphragm booster pump septation sheet, and make also increase more than the twice reaching original the working life of whole diaphragm booster pump thereupon, there is high industrial usability and practicability very much, and meet the important document of patent, be file an application in accordance with the law.

Claims (5)

1. the swing wheel structure improvement of a diaphragm booster pump, comprising:

One motor;

One motor protecgulum, its central build-in has a bearing, and is placed by the force-output shaft of motor, is convexly equipped with a circle epirelief annulus, and on the inner edge surface of this epirelief annulus, is provided with several fixing perforation in outer periphery;

One inclination eccentric cam, its central authorities run through an axis hole, and cover is fixed on the force-output shaft of motor;

One escapement seat, its bottom center build-in has an escapement bearing, and be nested with on inclination eccentric cam, the end face equi-spaced apart arrangement of its pedestal is convexly equipped with three cylinder escapements, the horizontal top surface of each cylinder escapement is arranged with a tapped hole, and is arranged with a delineation circle of position ring groove again in the periphery of this tapped hole;

One pump head seat, that cover is placed on the epirelief annulus of motor protecgulum, its end face is equipped with three equi-spaced apart and is greater than the start perforation of three cylinder escapement external diameters in escapement seat, make three cylinder escapements can be placed through in three start perforation, its bottom surface is to having dome ring under a circle again, the yardstick of this lower dome ring is identical with the epirelief annulus yardstick of motor protecgulum, the another end face down convex annular direction near outer periphery, then is equipped with several fixing perforation;

One diaphragm, be placed on the end face of pump head seat, by semi-rigid elastic material ejection formation, its outermost periphery end face is equipped with two circles and parallels opposed outer raised line and interior raised line, and give off three roads by end face central position and to connect with this interior raised line the fin connected, between Shi Gai tri-road fin and interior raised line, three piston start districts have been separated out between quilt, and each piston start district corresponds on the tapped hole position of each cylinder escapement end face in escapement seat, respectively be equipped with a central perforation again, and be convexly equipped with a circle positioning convex ring block in the diaphragm bottom surface being positioned at each central perforation,

Three piston thrust blocks, be placed in three piston start districts of diaphragm respectively, each piston thrust block runs through and is provided with a shoulder hole, three of diaphragm bottom surface positioning convex ring blocks are plugged in the location concave ring groove of three cylinder escapements in escapement seat respectively, the shoulder hole into piston thrust block is worn again with retaining screw, and after passing the central perforation in three piston start districts in diaphragm, can diaphragm and three piston thrust blocks be fixed in the tapped hole of three cylindrical escapement in escapement seat simultaneously;

One piston valve body, be placed on diaphragm, its bottom outer peripheral edge side is convexly equipped with a ring raised line downwards, the space between diaphragm China and foreign countries' raised line and interior raised line can be plugged, the circular drainage seat that an end face has concave arc surface is being provided with towards the middle position in pump head lid direction, and be equipped with a positioning hole in the central authorities of drainage seat, can penetrate fixing for a T-shaped non-return rubber cushion, on the region of the another 120 degree of angular position in each interval centered by this positioning hole, respectively be equipped with several weep hole, and to should in the drainage seat peripheral surface in three area sewerage holes, be equipped with again spaced 120 degree of angles arrangement respectively and opening three influent bases all down, each influent base is equipped with again several water inlet, and place the T-shaped piston sheet of a handstand in the central authorities of each influent base, and

One pump head lid, be covered on pump head seat, and by diaphragm and piston valve body coated, its outer edge surface is provided with a water intake, a water outlet and several fixing perforation, a scalariform groove is provided with in the bottom part ring of inner edge surface, assemblying body outer rim after diaphragm and piston valve body can being coincided mutually, is closely attached on this scalariform groove, and separately within it edge face central authorities are provided with a circle dome ring;

It is characterized in that: in each cylinder escapement of this escapement seat, horizontal top surface is located the region setting tool one-tenth of concave ring groove to vertical side edge face to lower inclined plane.

2. the swing wheel structure improvement of diaphragm booster pump according to claim 1, it is characterized in that: in this escapement seat, the diameter of each cylinder escapement changes and strengthens, but still be less than the internal diameter of start perforation in pump head seat, and the edge surface that becomes to slope inwardly by its edge surface setting tool, and in this each cylinder escapement, horizontal top surface is located the region setting tool one-tenth of concave ring groove to this edge surface that slopes inwardly to lower inclined plane.

3. the swing wheel structure improvement of diaphragm booster pump according to claim 2, it is characterized in that: this each cylinder escapement changes to be set as and is made up of a cylindrical seat and an escapement annulus, wherein, the circumferential outer edge face of this cylindrical seat is provided with one plane of orientation, and be provided with a protruding circular column end face is convex, and the end face fovea centralis of this protruding circular column is provided with a tapped hole, this escapement annulus is nested with on cylindrical seat, its outer periphery face is set as the edge surface that slopes inwardly, and be provided with mutually through hole, upper rank in end face central authorities toward direction, bottom surface, scala media hole and hole, lower rank, wherein, the aperture in hole, upper rank is greater than the external diameter of protruding circular column in cylindrical seat, the internal diameter in scala media hole is identical with the external diameter of protruding circular column in cylindrical seat, the internal diameter in hole, lower rank is identical with the external diameter of cylindrical seat, separately be set as to lower inclined plane by hole, upper rank to the region of the edge surface that slopes inwardly, this escapement annulus is made to be nested with after cylindrical seat, one can be formed between the protruding circular column of cylindrical seat and the hole, upper rank of escapement annulus and locate concave ring groove.

4. the swing wheel structure improvement of diaphragm booster pump according to claim 1, is characterized in that: this motor has carbon brush motor.

5. the swing wheel structure improvement of diaphragm booster pump according to claim 1, is characterized in that: this motor is non-carbonate motor.