CN102235524A - Array rotary valve - Google Patents

Abstract

The invention relates to an array rotary valve, and the array rotary valve can be used for realizing sequential and controllable flowing of a medium by virtue of rotating one part of a valve body. Under the cooperation of a valve core, a moving ring and a mating ring, the hole of the valve core is communicated with a hole on the inner circle of the moving ring all the time, the moving ring is driven to rotate, and one or a plurality of delivery pipelines are successively communicated or closed, thus the plurality of delivery pipelines can be sequentially and synchronously opened and closed, and one-to-more, few-to-more, more-to-few, more-to-one medium delivery can realized so that the medium can be sequentially and controllably delivered as required.

Description

The array rotary valve

Technical field: the present invention relates to a kind of control valve of realizing the orderly controllable flow of medium, medium can be gas, liquid, semisolid, solid particle and powder art.

Background technique: at present, known control valve will realize one the tunnel to multichannel, and few road is to need a plurality of valves and a plurality of electrical apparatus element to the media flow of multichannel, and the volume that combines is big, pipeline is many, circuit is complicated, and such structure is must the fault point many, poor reliability.

Summary of the invention:, the invention provides a kind of array rotary valve in order to overcome existing labyrinth.This valve can realize one the tunnel to multichannel, few road to multichannel, multichannel to few road, multichannel to one tunnel medium transport.Volume is little, and is simple in structure, easy to use, easy to control, and the fault point is few, stable.

Description of drawings further specifies the utility model below in conjunction with accompanying drawing:

Fig. 1 is the ssembly drawing of the first embodiment of the present invention;

Fig. 2 is the assembling view of first embodiment of the invention;

Fig. 3 is the sectional drawing of stationary ring 5 in the first embodiment of the invention ssembly drawing;

Fig. 4 is the sectional drawing of rotating ring 4 in the first embodiment of the invention ssembly drawing;

Fig. 5 is the sectional drawing of spool 3 in the first embodiment of the invention ssembly drawing;

Fig. 6 is the assembling view of second embodiment of the invention;

Fig. 7 is the sectional drawing of stationary ring 3 in the second embodiment of the invention ssembly drawing;

Fig. 8 is the sectional drawing of rotating ring 2 in the second embodiment of the invention ssembly drawing;

The sectional drawing of stationary ring 3 in Fig. 9 second embodiment of the invention ssembly drawing;

Figure 10 is the assembling view of third embodiment of the invention;

Figure 11 is the sectional drawing of stationary ring 1 in the third embodiment of the invention assembling view;

Figure 12 is the sectional drawing of rotating ring 2 in the third embodiment of the invention assembling view;

Figure 13 is the sectional drawing of spool 4 and plug 3 in the third embodiment of the invention assembling view;

Figure 14 is the fourth embodiment of the invention assembling view;

Figure 15 is the sectional drawing of stationary ring 2 in the fourth embodiment of the invention ssembly drawing;

Figure 16 is the sectional drawing of rotating ring 1 in the fourth embodiment of the invention ssembly drawing;

Figure 17 is the sectional drawing of spool 3 in the fourth embodiment of the invention ssembly drawing;

Figure 18 is the fifth embodiment of the invention assembling view;

Figure 19 is the sectional drawing of stationary ring 1 in the fifth embodiment of the invention ssembly drawing;

Figure 20 is the sectional drawing of rotating ring 2 in the fifth embodiment of the invention ssembly drawing;

Figure 21 is the sectional drawing of spool 3 in the fifth embodiment of the invention ssembly drawing;

Figure 22 is the sixth embodiment of the invention assembling view;

Figure 23 is the sectional drawing of stationary ring 2 in the sixth embodiment of the invention ssembly drawing;

Figure 24 is the sectional drawing of rotating ring 1 in the sixth embodiment of the invention ssembly drawing;

Figure 25 is the sectional drawing of spool 7 in the sixth embodiment of the invention ssembly drawing;

Among first embodiment Fig. 1: 1 is plug wire, and 2 is jump ring, 3 spools, and 4 is rotating ring, and 5 is stationary ring, and 6 is the radial hole of spool, and 7 is the stationary ring radial hole, and 8 is the rotating ring radial hole, and 9 is the spool groove, and 10 is the spool axial bore.

Among Fig. 1, the spool of array rotary valve (3) has 3 axial bores (10), and radial hole (6) is all arranged on 3 axial bores, and quantity is respectively 1,2,3, and fluted on the spool (9), the quantity of groove is corresponding with the radial hole of position and spool.6 radial holes (8) are arranged on the rotating ring (4), and on different cross sections, each hole all communicates with the spool groove respectively.Last 6 cross sections of stationary ring (5) have radial hole (7), and the quantity in hole is the position of the corresponding radial hole of 8 and rotating ring on same cross section.Medium flows to rotating ring by the axial bore of spool through each spool radial hole, the angle of a setting of the every rotation of rotating ring, and medium will flow out from the stationary ring radial hole of connecting.

Under above-mentioned situation, spool can have one or more axial bores, each axial bore of spool can be communicated with one or more radial holes as required, the corresponding spool groove of each spool radial hole, each spool groove is connected all radial holes on cross section of rotating ring, and each rotating ring radial hole can be by the corresponding radial hole on connection of rotation rotating ring and the same cross section of stationary ring.Medium is flow in the corresponding spool groove to the hole by the spool disalignment, the corresponding radial hole that flows to stationary ring by the corresponding radial hole on the rotating ring flows in the external pipeline of stationary ring again, external force drives rotating ring and rotates a certain angle, make on next row radial hole and the stationary ring on the rotating ring corresponding radial hole connect as required and close, realize the orderly controlled delivery of medium.Medium also can reverse flow, is entered by rotating ring by stationary ring and flows out from spool, and the rotating ring rotation makes the hole on the rotating ring connect as required with the different holes on the stationary ring, the conveying of realization same media or the proportioning according to quantity of different medium.

Among second embodiment Fig. 6,1 is jump ring, and 2 is rotating ring, and 3 is stationary ring, and 4 is the rotating ring radial hole, and 5 is the stationary ring radial hole, and 6 is the rotating ring axial bore, and 7 is the spool axial bore, and 8 is spool.

Spool among Fig. 6 (8) is rotatable joint, and rotating ring (2) connecting end follow-up ring rotates together, and the other end does not rotate, external pipeline.The axial bore of spool (7) is directly identical with the axial bore (6) of rotating ring, rotating ring axial bore (6) is communicated with the radial hole (4) of a plurality of different cross sections, a radial hole is arranged on each cross section of rotating ring, the angle of a setting of the every rotation of rotating ring, have only a radial hole and stationary ring (3) on the rotating ring ' last radial hole connection, the hole Close All in other cross section.Realize one tunnel accurate quantification medium transport to multichannel.Also can there be a plurality of radial holes in the same cross section of rotating ring, by the different arrangements in hole on rotating ring and the stationary ring, can realize the medium transport of multiple mode.

Among the 3rd embodiment Figure 10,1 is stationary ring, and 2 is rotating ring, and 3 is plug, and 4 is spool, and 5 is the stationary ring radial hole, and 6 is the rotating ring radial hole, and 7 is the axial bore of spool.

Among the 4th embodiment Figure 14,1 is rotating ring, and 2 is stationary ring, and 3 is spool, and 4 is the stationary ring radial hole, and 5 is the spool axial bore, and 6 is the radial hole of rotating ring.

Among the 5th embodiment Figure 18,1 is stationary ring, and 2 is rotating ring, and 3 is spool, and 4 is the rotating ring radial hole, and 5 is the spool axial bore, and 6 is the radial hole of stationary ring.

Third and fourth, five embodiments are array rotary valve y=1, the structural drawing during z=1, the 3rd, five embodiments are swivel joints of spool different structure, spool directly is connected with rotating ring, spool is connected with stationary ring among the 3rd embodiment, the axial bore of spool enters rotating ring.Their characteristics are to have only a plurality of radial holes on a radial hole and the stationary ring on the rotating ring in a cross section, the rotating ring rotation, and the radial hole of rotating ring and the radial hole of stationary ring are connected one by one and are closed.Realize one tunnel accurate quantification medium transport to multichannel.Rotating ring also can be a plurality of radial holes, by the different arrangements in hole on rotating ring and the stationary ring, can realize the medium transport of different modes.

Among the 6th embodiment Figure 22,1 is rotating ring, and 2 is stationary ring, and 3 is the rotating ring radial hole, and 4 is the stationary ring radial hole, and 5 is the rotating ring axial bore, and 6 is the spool axial bore, and 7 is spool.

Among Figure 22, the profile of stationary ring (2) is a cuboid, all has the interior circle of 9 radial holes (4) and stationary ring to communicate on 4 planes, and 9 radial holes on the same plane and have the radial hole of four Different Plane on the same cross section on different cross sections.9 radial holes (3) are arranged on the rotating ring (1), and curl is arranged, the corresponding aperture of each hole and stationary ring on a cross section.Spool (7) is a swivel joint.The interior circle of the cylindrical of rotating ring and stationary ring matches, and spool is directly connected on the rotating ring.Medium is entered the axial bore (5) of rotating ring by the axial bore (6) of spool, again by the radial hole flow direction of rotating ring and the stationary ring radial hole of its connection, the angle of a setting of rotating ring rotation, the next radial hole of rotating ring is connected with another hole of stationary ring again, and other holes all are in closed condition.The rotating ring angle of swing that circulates has as requested realized medium controlled conveying in order like this.

Embodiment:

The present invention solves the scheme that its technical problem adopts: an outer toroid is that n hole, n 〉=1 are arranged on the stationary ring; The middle annulus that matches with the interior circle of stationary ring is that x hole, x 〉=1 are arranged on the rotating ring; Above the spool that matches with the interior circle of rotating ring Z groove arranged, Y hole arranged, y 〉=1, and z 〉=y, x 〉=z, n 〉=x in the spool.Groove on the spool and the hole on the rotating ring are communicated with all the time.When rotating ring rotated, hole on the rotating ring and the hole on the stationary ring were connected as required, and the medium in the hole is flowed according to quantity.Reaching simply and easily, structure realizes complicated function.

The invention has the beneficial effects as follows,, connect or close one or more delivery line successively, and can realize sequence switch and synchronous switch that multichannel is carried, make medium controlled delivery as required in order by the rotation of rotating ring.

Claims (3)

1. array rotary valve, it is characterized in that: by a cylindrical stationary ring, a middle circle rotating ring, interior round valve core three parts are formed, between spool and the rotating ring movingly, seal isolation between the spool groove, the spool axial bore is communicated with all the time by the radial hole on spool groove and the rotating ring, between rotating ring and the stationary ring movingly, the relative rotating ring transfixion of spool with stationary ring, rotating ring rotation makes radial hole corresponding on radial hole and the stationary ring on the rotating ring connect as required or close.

2. array rotary valve according to claim 1 is characterized in that: the interior circle of stationary ring and rotating ring and spool are concentric circles, and the shape of the outer surface of stationary ring can be circular, can be other shape also, n radial hole arranged on the stationary ring, also can make one-way valve structures in each hole, there is x radial hole n 〉=1, x 〉=1 on the rotating ring, spool has y axial bore, the spool groove that has z radial hole to be communicated with, y 〉=1, z 〉=y, x 〉=z, n 〉=x, when y=1, spool can be a swivel joint.

3. array rotary valve according to claim 2 is characterized in that: the numeral of n, x, y, z is decided as required, and the structural type in the hole on stationary ring, rotating ring and the spool is permutation and combination as required.

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