KR20130029375A - Branched duct construct, and uniaxial eccentric screw pump system - Google Patents

Abstract

The present invention provides a branch flow path structure and a branch flow path structure capable of branching a fluid to a desired number of branches and disposing the discharge portion of each branch flow path at a desired position, and equalizing discharge pressure and discharge amount in each branch flow path. The purpose was to provide a single uniaxial eccentric screw pump system.
The branch flow path Bn of the branch flow path structure has n relay parts Rn so as to correspond to each of the n discharge parts Fn, and introduces an n-system connecting the inlet part S and the relay part Rn. The relay part flow path SRn and the n-type relay / discharge part flow path RFn which connect the said n relay parts Rn and the discharge part Fn are provided. Further, in the branch flow path structure, the relay part Rn is disposed at a position corresponding to n dividing the circumference of the virtual circle centered on one point on the vertical line passing through the axis of the inlet part S, and the n line Branch flow path Bn is formed so that the length of flow path RFn between a relay and a discharge part may become the same, respectively.

Description

BRANCHED DUCT CONSTRUCT, AND UNIAXIAL ECCENTRIC SCREW PUMP SYSTEM}

The present invention relates to a branch flow path structure capable of branching a fluid introduced into the introduction portion into a plurality of systems, and a uniaxial eccentric screw pump system having the branch flow path structure.

Conventionally, when branching the non-conveyed material (fluid) conveyed by the uniaxial eccentric screw pump as disclosed in Patent Document 1 below into a plurality of flow paths, the flow path connected to the uniaxial eccentric screw pump is sequentially branched. Measures are adopted. In addition, conventionally, by adjusting valves, nozzles, etc. in each branch flow path, and taking measures such as fine adjustment individually, stabilization of the discharge pressure and the discharge amount in each branch flow path is achieved.

Japanese Patent Application Publication No. 2008-175199

However, when branching the flow path connected to the uniaxial eccentric screw pump as described above, the branch number is limited to two powers of n (n = natural number) in order to equalize the discharge pressure and the discharge amount, and branch to the desired branch number. There is a problem that it may not be possible. Moreover, in order to arrange | position arbitrary each branch flow path, there exists a problem that it becomes more difficult to equalize the discharge pressure and discharge amount of the fluid discharged from each branch flow path. Specifically, there is a problem that complicated adjustment is required, such as a valve, a nozzle, or the like, provided in each branch flow path, and finely adjusting them to adjust the discharge pressure and the discharge amount. Therefore, in the prior art, it is extremely difficult to form the branch flow path so that the fluid can be discharged to the desired position with the desired number of branches, and there is a problem that a significant restriction is applied in the flow path design.

In addition, in the case where a valve, a nozzle, or the like is provided in each branch flow path and fine adjustments are made to take measures to adjust the discharge pressure and the discharge amount, the above-described fine adjustment of the valve and the nozzle is required. There is a problem that it is extremely difficult to achieve uniformity of discharge amount.

Therefore, the present invention can branch the fluid discharged from the uniaxial eccentric screw pump or the like into a desired number of branches, and arrange the discharge portion of each branch flow path at a desired position, and at the same time easily and appropriately, discharge in each branch flow path. An object of the present invention is to provide a uniaxial eccentric screw pump system provided with a branch flow path structure capable of achieving uniform pressure and discharge amount and the branch flow path structure.

The branch flow path structure of the present invention provided to solve the above-described problems can constitute a branch flow path for evenly discharging the fluid introduced from the introduction portion from the n discharge portions. In the branch flow path structure of the present invention, n relay parts are provided so as to correspond to each of the n discharge parts, the flow path between the n system introduction and relay parts connecting the introduction part and the n relay parts, and the n relay parts. And an n-system relay / discharge unit connecting the discharge unit corresponding to the relay unit. Further, in the branch flow path structure of the present invention, the relay portion is disposed at a position corresponding to n dividing the circumference of the virtual circle centered on one point on the vertical line passing through the axis of the introduction portion, and relaying and discharging the n-system. The lengths of the flow paths between the sections are the same, respectively.

In the branch flow path structure of the present invention, it is preferable that the relay portion is disposed at a position where the circumference of the virtual circle is divided approximately n equally.

The branch flow passage structure according to the present invention includes a lower portion through which a flow path between the relay and discharge portions can flow fluid downward, and a horizontal portion capable of flowing fluid in a horizontal direction, wherein the horizontal portion and the lower portion A flow path having a bent portion between the sections, the sum of the lengths of the horizontal portions in relation to the flow path between the relays and the discharge sections is the same, and the sum of the lengths of the descending sections in the flow path between the relay and discharge sections being the same; It is preferable that the number of the said bent part in the flow path between discharge parts is the same.

Further, it is preferable that a plurality of bent portions are formed in the vertical direction in the flow path between each relay / discharge portion constituting the branch flow path structure of the present invention.

The branch flow path structure according to the present invention can also be provided with a diameter reduction portion having a reduced flow path diameter in the flow path between the relay and discharge portions.

In the branch flow path structure of the present invention, it is preferable that the flow path diameter in each portion constituting each branch flow path is substantially uniform regardless of the branch flow path.

The branch flow path structure of the present invention may be configured by overlapping plates with grooves constituting the branch flow paths. Moreover, it is preferable that the branched flow path structure of the present invention has a circular cross section or a n × a square (a is any natural number).

The uniaxial eccentric screw pump system of the present invention has the branch flow path structure of the present invention and the uniaxial eccentric screw pump described above, and enables the fluid discharged from the uniaxial eccentric screw pump to be introduced into the introduction portion of the branch flow path structure.

In the branch flow path structure of the present invention, the relay portion is provided at a position corresponding to n dividing the circumference of the virtual circle centered on one point on the vertical line passing through the axis of the introduction portion. Moreover, since the flow path between the n system introduction and relay sections is provided so as to connect the introduction section and each relay section, the length of the flow path between the introduction and relay sections is uniform for each system. Therefore, in the section from the introduction section to the relay section, the fluid flows at approximately uniform pressure and flow rate in each branch flow path. In addition, in the branch flow path structure of the present invention, the length of the flow path between the n relay and discharge portions extending from the n relay portions to the n discharge portions is uniform, so that fluid flows through the flow path between the relay and discharge portions. It is possible to attain a pressure loss generated and a uniform flow rate of the fluid. Therefore, according to the branch flow path structure of the present invention, it is possible to branch the fluid introduced into the introduction portion to the desired number of branches while making the discharge amount and the discharge pressure substantially constant.

In the branch flow path structure of the present invention, it is possible to achieve uniform discharge amount and discharge pressure in each discharge part without providing a valve or nozzle separately. Therefore, it becomes possible to simplify a flow path structure, and it becomes possible to suppress the effort of installation work and maintenance to the minimum as much as the adjustment of the above-mentioned valve and nozzle becomes unnecessary.

In addition, in the branch flow path structure of the present invention, the length of the flow path between each relay / discharge portion may be uniform, and no particular limitation is placed on the arrangement. Therefore, according to the branch flow path structure of this invention, it becomes possible to arrange | position the discharge part of each branch flow path in a desired position, and the freedom in flow path design becomes extremely high.

In the branch flow path structure of the present invention, by arranging the relay parts at positions that substantially divide the virtual circle at the concentric position with the introduction part, the flow rate and pressure of the fluid flowing through the flow path between the respective introduction and relay parts can be more uniformly ensured. It becomes possible. Therefore, according to this invention, it becomes possible to make the flow volume and discharge pressure of the fluid in each discharge part more uniform.

As described above, the branch flow path structure according to the present invention is a flow path in which the flow path between each relay / discharge part is provided with a descending part and a horizontal part and is curved, and the sum of the length of the horizontal part and the sum of the lengths of the descending part are respectively relayed and By equalizing the flow paths between the discharge parts and equalizing the number of the bent portions in the flow paths between the relay and the discharge parts, the pressure loss and the flow rate distribution caused by the flow of fluid through the flow paths between the relay and the discharge parts are equalized. It becomes possible. Therefore, by making the flow path between each relay / discharge part into the flow path which has the above-mentioned curved flow path structure part, it becomes possible to further equalize the flow volume and discharge pressure of the fluid in each discharge part.

In addition, when the said flow path between each relay and discharge part is provided with two or more curved parts in the up-down direction, the horizontal part located in the upstream side rather than the direction of the horizontal part located downstream of the flow direction of a fluid with respect to a curved part. It becomes possible to face in a direction different from that, and it becomes possible to raise the degree of freedom of the layout of each discharge part by that much.

In addition, the branch flow path structure of the present invention makes it possible to substantially uniform the discharge amount and the discharge pressure in the discharge portion connected to each branch flow path by making the flow path diameters of the branch flow paths substantially uniform regardless of the branch flow paths. As described above, in the present invention, in the case of providing a diameter reducing portion in which the flow path diameter is reduced in the middle of the flow path between the introduction / relay portion or the relay / discharge portion, or in the case of providing a diameter expansion portion in which the flow path diameter is enlarged, The flow rate and discharge pressure in each branch flow path can be made substantially uniform by making the flow path diameters of the diameter reduction part and the diameter expansion part substantially uniform regardless of the branch flow path. Thus, by making the diameter of the flow path at each part of the branch flow path substantially uniform regardless of the branch flow path system, it becomes possible to achieve substantially uniform flow conditions such as pressure loss caused by the flow of the fluid, and to discharge each discharge. It becomes possible to attain substantially uniformity of the discharge amount and the discharge pressure in the negative portion.

In the branch flow passage structure according to the present invention, it is possible to easily and reliably form a branch flow path that satisfies the above conditions by forming the branch flow paths by stacking the grooved plates. Moreover, when it is set as such a structure, assembling, disassembly, cleaning, etc. of a branch flow path structure are easy and it becomes easy to install and maintain a branch flow path structure.

In addition, the branch flow path structure according to the present invention is formed so that the inlet portion has a circular cross section or a regular n × a square (a is an arbitrary natural number), so that the inflow passage flows into each of the flow paths between the inlet and the relay portion formed by n systems. The flow rate and pressure of the fluid can be made uniform.

Since the uniaxial eccentric screw pump system of the present invention has the branch flow path structure of the present invention and the uniaxial eccentric screw pump described above, the fluid discharged from the uniaxial eccentric screw pump can be introduced into the inlet of the branch flow path structure, so that the uniaxial eccentric screw pump It is possible to branch the fluid supplied from the pump to the desired branch water, and to arrange the discharge portion of each branch flow path at a desired position. In addition, in the uniaxial eccentric screw pump system of the present invention, it is possible to easily and appropriately equalize the discharge pressure and the discharge amount in each branch flow path.

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which shows the uniaxial eccentric screw pump system which concerns on one Embodiment of this invention.
FIG.2 (a) is a top view which shows the branch flow path structure which concerns on one Embodiment of this invention, (b) is this side view.
FIG. 3 is a perspective view illustrating a configuration of branch flow paths formed in the branch flow path structure shown in FIG. 2.
4 is a perspective view for explaining the configuration of the branch flow path.
5 is an explanatory diagram for explaining a method for designing a path between a relay section and an introduction / intermediate section in the flow path design of the branch flow path.
6 is an explanatory view for explaining a design method of a horizontal portion of a flow path between a relay portion and a discharge portion connecting the relay portion and the discharge portion in the flow path design of the branch flow passage.
7 (a) and 7 (b) are explanatory diagrams showing a modified example of the conduit constituting each branch flow path.
8 (a) and 8 (b) are explanatory views showing modifications of the introduction portion, respectively.

Subsequently, the uniaxial eccentric screw pump system 1 (hereinafter also referred to simply as the "pump system 1") and the branch flow path structure 50 of the present invention will be described in detail with reference to the drawings. The pump system 1 is comprised by the combination of the uniaxial eccentric screw pump 5 and the branch flow path structure 50. Although the pump system 1 of this embodiment has the characteristics in the branch flow-path structure 50, the structure of the uniaxial eccentric screw pump 5 is outlined prior to this description.

≪About uniaxial eccentric screw pump (5) ≫

The uniaxial eccentric screw pump 5 is a so-called rotary displacement pump and has a structure in which a stator 10, a rotor 30, a power transmission mechanism 40, and the like are housed inside the casing 20. As shown in FIG. 2, the stator 10 is a member incorporated in the uniaxial eccentric screw pump 5, and is a cylinder having a long cross-sectional shape and having two sets of female threaded holes. The stator 10 is formed of rubber or the like. The kind of rubber which comprises the stator 10 can be suitably selected according to the kind, property, etc. of the to-be-conveyed object conveyed by the uniaxial eccentric screw pump 5.

The casing 20 is a metal member and is a cylindrical member, and the first opening 22a is formed in the disk-shaped end stud 20a provided in the longitudinal direction one end side. Moreover, the 2nd opening 22b is formed in the outer peripheral part of the casing 20. As shown in FIG. The second opening 22b communicates with the inner space of the casing 20 in the middle portion 20d located in the longitudinal middle portion of the casing 20. The first and second openings 22a and 22b function as the discharge port and the suction port of the uniaxial eccentric screw pump 5, respectively. The stator 10 mentioned above is accommodated in the stator mounting part 22c provided in the position adjacent to the 1st opening 22a in the casing 20, and is being fixed. The stator 10 fits the flange portion 10a at the end of the casing 20 by the end studs 20a, and applies the stay bolt 24 over the end studs 20a and the main body portion of the casing 20. It is fixed by installing and tightening.

The rotor 30 is a metal shaft and has a set of male threads. The rotor 30 is inserted through the stator 10 described above, and is freely eccentrically rotatable inside the stator 10. The rotor 30 is inserted into the through-hole 16 of the stator 10 mentioned above, and the outer peripheral surface of the rotor 30 and the inner peripheral surface of the stator 10 are in contact with both tangents. In this state, the fluid transfer path 32 is formed between the inner circumferential surface of the stator 10, which forms the through hole 16, and the outer circumferential surface of the rotor 30.

The fluid conveyance path 32 extends in a helical shape toward the longitudinal direction of the stator 10 and the rotor 30, and when the rotor 30 is rotated in the through-hole 16 of the stator 10, the stator ( 10) Proceed in the longitudinal direction of the stator 10 while rotating the inside. Therefore, when the rotor 30 is rotated, the fluid is sucked into the fluid conveying path 32 from one end side of the stator 10 and the fluid is trapped in the fluid conveying path 32. It is possible to convey toward the other end side and discharge on the other end side of the stator 10.

The power transmission mechanism 40 is provided for transmitting power to the above-described rotor 30 from a power source (not shown) such as a motor provided outside the casing 20. The power transmission mechanism 40 transmits the rotational power transmitted from the above-mentioned power source to the rotor 30, and the rotor 30 can be eccentrically rotated. The uniaxial eccentric screw pump 5 can convey a fluid through the fluid conveyance path 32 by operating the above-mentioned power source and rotating the rotor 30.

≪About branch euro structure 50] ≫

The branch flow path structure 50 is connected to the first opening 22a serving as the discharge port of the uniaxial eccentric screw pump 5 having the above-described configuration. As shown in FIG. 2, the branch flow path structure 50 is formed by integrating metal flow path forming plates P1 to P4 by bolts inserted through the plates so as to penetrate between the plates P1 to P4 in the vertical direction. . The branch flow path structure 50 is each of the introduction portion S and the n discharge portions Fn in addition to the introduction portion S and n discharge portions Fn (n is a natural number of two or more. N branching flow paths (Bn) for connecting the two, and the fluid introduced into the inlet (S) is branched approximately equally to the n-branch flow paths (Bn) from each of the n discharge parts (Fn) It is possible to discharge.

The flow path configuring plates P1 to P4 are provided with grooves constituting the n-type branch flow path Bn connecting them in addition to the above-described introduction portion S or n discharge parts Fn. Hereinafter, the structure of the introduction part S, the n discharge parts Fn, and the branched flow path Bn of the n system will be described in more detail.

As shown in FIG. 2 or FIG. 3, the introduction portion S is a portion having a substantially circular cross-sectional shape provided in the flow path configuration plate P1 disposed at the uppermost portion in the branch flow path structure 50. The flow path constitution plate P1 is a disk-shaped and metal plate, and the introduction portion S is provided at approximately the center of the flow path constitution plate P1. Moreover, the discharge part Fn is provided in the flow path constitution plate P4 which is disposed in the lowermost part of the branch flow path structure 50. Although the arrangement | positioning and the number (n pieces) of discharge parts Fn can be arbitrary, in this embodiment, as shown in FIG. 3, seven discharge parts Fn (n = 1-7) are straight lines L. As shown in FIG. It is formed to be arranged on a phase.

The branch flow path Bn is constituted by grooves formed in the flow path configuring plates P1 to P4. The branch flow paths Bn are formed by n lines corresponding to each of the n discharge parts Fn (n = 1 to 7) provided. That is, the first to nth branch flow paths Bn are formed. In the present embodiment, since seven discharge portions Fn are provided, seven branch flow paths Bn including the first branch flow paths B1 to 7th branch flow path B7 are formed.

As shown in Fig. 4, the branch flow paths Bn (n = 1 to 7) are each relay portions Rn (n = 1 to 7) provided corresponding to the discharge portions Fn (n = 1 to 7). Flow path SRn (n = 1 to 7) between each of the inlet and relay portions connecting the inlet and the inlet S, each of the relay portions Rn (n = 1 to 7) and each of the discharge portions Fn (n = 1). It is largely distinguished by the flow path RFn (n = 1-7) between the relay / discharge parts connecting 7 to 7). The flow path SRn (n = 1 to 7) between each introduction / relay part and the flow path RFn (n = 1 to 7) between each relay / discharge part are respectively connected and form a series of flow paths.

As shown in FIG. 5, the relay part Rn (n = 1-7) is arrange | positioned on the virtual circle C1 concentric with the introduction part S mentioned above. In addition, relay part Rn (n = 1-7) is arrange | positioned in the position which divides the circumference of virtual circle C1 by n (7 division in this embodiment). The relay unit Rn (n = 1 to 7) should be arranged so as to divide the circumference of the virtual circle C1 by n, but consider supplying the fluid substantially equally to each branch flow path Bn (n = 1 to 7). In other words, it is preferable to arrange the circumference of the virtual circle C1 at approximately n equal positions. From this point of view, in the present embodiment, the relay section Rn (n = 1 to 7) is disposed at a position that substantially divides the circumference of the virtual circle C1 into n equal parts (in this embodiment, seven equal parts). Therefore, the flow path SRn (n = 1-7) between each introduction / relay part is formed radially centering on the introduction part S. As shown in FIG.

As shown in Fig. 4, the flow path RFn (n = 1 to 7) between the relay and the discharging portion is the lower portion Dnp (n = 1 to 7, p = 1 to 3) and the horizontal portion Lnq. ) (n = 1 to 7, q = 1 to 2), and is a curved flow path formed by communicating them. Specifically, the flow path RFn (n = 1 to 7) between each relay / discharge part communicates with the descending part Dn1 → horizontal part Ln1 → lower part Dn2 → horizontal part Ln2 → lower part Dn3, and discharge part ( It is a flow path formed so as to be connected to Fn) (n = 1-7).

In this embodiment, the length of each descent | falling part Dnp and each horizontal part Lnq is substantially the same for every system, and internal diameter is also substantially the same. Therefore, the total length and the opening diameter of the flow path RFn between the relay and the discharging portion are substantially the same regardless of the system, and become substantially uniform with respect to the pressure loss generated by the passage of the fluid inside.

≪About design method of branch flow path (Bn) ≫

Subsequently, the design method of the branch flow path Bn (n = 1 to 7) mentioned above is demonstrated. In the branch flow path Bn, the lower portions Dn1, Dn2, and Dn3 (n = 1 to 7) are formed by through holes having the same opening diameter, respectively, formed to penetrate the flow path configuring plates P2, P3, and P4 in the vertical direction. . Therefore, the length and opening diameter of the lower portions Dn1, Dn2, and Dn3 (n = 1 to 7) are uniform regardless of the system of the branch flow path Bn (n = 1 to 7). Therefore, in the case of designing the branch flow path B, a portion extending in the horizontal direction, specifically, the flow path SRn (n = 1 to 7) between the introduction and relay portions, and the flow path RFn between the relay and discharge portions (n) The arrangement of the horizontal portions Lnq (n = 1 to 7, q = 1 to 2) constituting = 1 to 7 becomes a problem. Hereinafter, the design method of the flow path SRn (n = 1 to 7) and the horizontal part Lnq (n = 1 to 7, q = 1 to 2) between the introduction and relay units will be described.

The flow path SRn (n = 1 to 7) between the introduction and relay portions and the horizontal portion Lnq (n = 1 to 7, q = 1 to 2) are the introduction portion S, the relay portion Rn, and the discharge. The positional relationship in the horizontal direction of the part Fn (n = 1 to 7) is determined on the basis of the point where these are projected on the virtual horizontal plane H. As shown in FIG. Specifically, the intersection of the vertical line passing through the axial position of the introduction portion S, the relay portion Rn, and the discharge portion Fn (n = 1 to 7) and the horizontal plane H, the introduction reference point s and the relay, respectively. It is set as the reference point rn and the discharge reference point fn (see Fig. 4).

Since the flow path SRn (n = 1 to 7) between the introduction and relay portions is a flow path connecting the introduction portion S and the relay portion Rn, it is necessary to determine the relay portion Rn (n = 1 to 7). . As shown in FIG. 5, the relay portion Rn (n = 1 to 7) has a virtual circle C1 having a radius r1 around the introduction reference point s set on the horizontal plane H corresponding to the introduction portion S. As shown in FIG. This is prescribed | regulated, and the relay reference point rn corresponding to relay part Rn (n = 1-7) is set in the position which divides the circumference of virtual circle C1 substantially n equally. In this embodiment, since it is necessary to form seven branches of the flow path Bn, the relay reference point rn (n = 1 to 7) is set every 360/7 [degrees] on the circumference of the virtual circle C1.

Here, the horizontal portion Ln1 (n = 1 to 7) is formed between the flow path configuring plates P2 and P3, and the horizontal portion Ln1 (n = 1 to 7) is formed in the horizontal direction on the basis of the position immediately below the relay portion Rn (n = 1 to 7). It is an extended passage. Further, the horizontal portion Ln2 (n = 1 to 7) is formed between the flow path configuring plates P3 and P4, and the horizontal portion Ln2 (n = 1 to 7) is formed in the horizontal direction on the basis of the position immediately above the discharge portion Fn (n = 1 to 7). It is an extended passage. In addition, the flow path length of the horizontal portion Ln1 (n = 1 to 7) needs to be uniform for each system, and the flow path length of the horizontal portion Ln2 (n = 1 to 7) also needs to be uniform for each system.

Therefore, in designing the horizontal portions Ln1 and Ln2, first, as shown in Fig. 6, the relay reference point rn (n) (n) set on the horizontal plane H so as to correspond to the discharge portions Fn (n = 1 to 7). The virtual circle C2n (n = 1 to 7) and the discharge reference point fn (n = 1 to 7) having a radius r2 centering on the points 1 to 7 and the virtual circle C2n (n = 1 to 7) and An imaginary circle C3n (n = 1 to 7) having an intersection radius r3 is set on the horizontal plane H. As shown in FIG. Thereby, the intersection of the formed virtual circle C2n (n = 1-7) and virtual circle C3n (n = 1-7) is defined as the bending reference point xn (n = 1-7).

Specifically, the design method of the first branch flow path B1 will be described as an example. In the design of the horizontal parts L11 and L12, the discharge reference point f1 is set at a position corresponding to the discharge part F1 as shown in FIG. 6. Moreover, the virtual circle C21 of radius r2 and the virtual circle C31 of radius r3 centering on the discharge reference point f1 are set centering on the relay reference point r1 assumed in the 1st branch flow path B1. The horizontal part L11 is set in the position which connects the intersection X1 of the virtual circle C21, C31 and the relay reference point r1, and the horizontal part L12 is set in the position which connects the intersection X1 and the discharge reference point f1. Similarly, the horizontal portions Ln1 and Ln2 (n = 1 to 7) of the second to seventh branch flow paths B2 to B7 are set.

When the relay reference point rn, the bending reference point xn and the discharge reference point fn are determined as described above, as shown in Fig. 4, vertical lines Vrn, Vxn, and Vfn passing through them are set. Further, a horizontal plane J1 passing between the flow path forming plates P1 and P2, a horizontal plane J2 passing through the flow path forming plates P2 and P3, and a horizontal plane J3 passing between the flow path forming plates P3 and P4 are assumed. The intersection of the vertical line Vrn and the horizontal plane J1 serves as a boundary between the flow path SRn (n = 1 to 7) and the descending part Dn1 between the introduction and relay portions. In addition, the intersection of the vertical line Vxn and the horizontal plane J2 becomes the boundary of the horizontal part Ln1 and the falling part Dn2, and the intersection of the vertical line Vxn and the horizontal plane J3 becomes the boundary part of the falling part Dn2 and the horizontal part Ln2. Further, the intersection of the vertical line Vfn and the horizontal plane J3 becomes the boundary between the horizontal part Ln2 and the falling part Dn3. By designing the flow path RFn (n = 1 to 7) between the introduction / middle part flow path Srn and the relay / discharge part in this way, the flow path length is the same, and the discharge part Fn is introduced from the introduction part S to each discharge part Fn. A series of branch flow paths Bn (n = 1 to 7) to be connected can be formed.

As described above, in the branch flow path structure 50 according to the present embodiment, n relay reference points are provided at positions for dividing the circumference of the virtual circle C1 with the center of the introduction reference point s at the concentric position with the introduction portion S by n. (rn) is set, and the relay part Rn is provided in the position corresponding to each relay reference point rn on the horizontal plane J1. In addition, since the flow path SRn between the introduction and relay portions of the n-system is provided so as to connect the introduction portion S and the relay portions Rn, the length of the flow passage SRn between the introduction and relay portions is uniform for each system. Therefore, in the branch flow path structure 50, the fluid introduced into the inlet part S from the uniaxial eccentric screw pump 5 reaches approximately to each branch flow path Bn in the section from the relay part Rn. It is possible to distribute at a uniform pressure and flow rate.

Moreover, in the branch flow path structure 50 of this embodiment, by designing according to the flow path design method mentioned above, each relay from the n relay parts Rn to each discharge part Fn provided correspondingly to them is carried out. The length of the flow path RFn between discharge parts is uniform, respectively. Therefore, in the branch flow path structure 50, it is possible to equalize the pressure loss and the flow rate of the fluid generated by the flow of the flow path RFn between each relay / discharge part, regardless of the branch flow path Bn. Therefore, according to the branch flow path structure 50, it becomes possible to branch the fluid introduced into the inlet S to the desired number of branches while making the discharge amount and the discharge pressure substantially constant.

As described above, by using the branch flow path structure 50, the discharge amount and discharge pressure of the fluid in each discharge portion Fn can be made uniform. Therefore, as in the prior art, it is not necessary to provide a valve, a nozzle, or the like for adjusting the discharge amount or the discharge pressure in each discharge part Fn or a flow path connected to this separately, and there is no need to adjust the valve or the nozzle. Therefore, when the fluid supplied from the uniaxial eccentric screw pump 5 is branched into a plurality of systems by using the branch flow channel structure 50 described above, the flow path configuration is simplified, and adjustment of the discharge amount and the discharge pressure is unnecessary. It is possible to minimize the effort required for maintenance and installation work.

By designing the flow path as described above, the branch flow path structure 50 has the same flow path length of the flow path SRn between the introduction / relay section and the flow path RFn between the relay / discharge section without using the branch flow path Bn. It is possible to let. Therefore, the branch flow path structure 50 can not only arrange the discharge portion Fn on a predetermined straight line as described above, but also can arrange the discharge portion Fn appropriately as desired, and the degree of freedom of layout selection of the discharge portion Fn. Is extremely high. Moreover, according to the branch flow path structure 50, it is possible to equalize the discharge amount and discharge pressure of the fluid in each discharge part Fn even if the number of discharge parts Fn is not n multiplied by 2 like the conventional technique. It is possible to appropriately adjust the number of discharge portions Fn as desired.

In the branch flow path structure 50 of the present embodiment, the sum of the lengths of the descending portions Dnp and the sum of the lengths of the horizontal portions Lnq are the same regardless of the branch flow path Bn. In addition, the branch flow path structure 50 has the size of the pipe constituting each part constituting each branch flow path Bn, specifically, the flow path SRn between the introduction and relay portions, and the flow path RFn between the relay and discharge portions. The cross-sectional shape is substantially the same. In addition, in each branching system Bn, the total number of the bending part formed in the boundary of the horizontal part Lnq and the falling part Dnp is the same. Therefore, the pressure loss and the uniformity of the flow rate distribution caused by the fluid flowing through the flow path RFn between each relay / discharge part are substantially uniform regardless of the system of the branch flow path Bn. The discharge amount and discharge pressure of the fluid can be made uniform.

The branch flow path Bn shown in the present embodiment exemplifies an example in which the horizontal portion Lnq and the lower portion Dnp are curved without being greatly curved at the boundary portion, but the present invention is not limited thereto. That is, since the branch flow path structure 50 of the present embodiment constitutes the branch flow paths Bn by overlapping the flow path forming plates P1 to P4 with grooves, the boundary between the horizontal part Lnq and the lower part Dnp. Although it was possible to make it continuous without large curvature, when the pipe of a copper pipe is bent and each branch flow path Bn is formed, the horizontal part Lnq and the lower part Dnp than what was shown by this embodiment, for example. In the boundary portion of the can not be greatly curved. Therefore, the branch flow path Bn may be a curved portion having a larger curvature than that shown in this embodiment as shown in Fig. 7A.

Also in the case where the boundary portion is largely curved as described above, the branch flow path Bn has substantially the same flow path length regardless of the system, and the sum of the lengths of the lower portions Dnp is the same regardless of the system. It is necessary to design the flow path so that the sum of the lengths of the horizontal portions Lnq is the same and the number of the bent portions is the same. As long as these conditions are satisfied, it is possible to make the discharge pressure and discharge amount of the fluid in each discharge part Fn substantially uniform, similar to what was illustrated in this embodiment.

In the branch flow path structure 50, the said flow path RFn between each said relay / discharge part is equipped with the bending part, and the direction of the horizontal part Lnq of the downstream side is made upstream (upper) rather than the bending part by making the bend part boundary. It is possible to face in a direction different from the horizontal part Lnq of the side). Moreover, the flow path RFn between the relay and the discharging portion has a configuration in which a bent portion is provided in a plurality of places in the vertical direction, respectively. Therefore, the branch flow path structure 50 can reach the flow path RFn between each relay / discharge part to an arbitrary position in the horizontal direction in accordance with the layout of each discharge part Fn, and the freedom in flow path structure is high.

Although the opening diameter of the flow path which comprises each branch flow path Bn was uniform regardless of a site | part, although the branch flow path structure 50 shown in this embodiment was uniform, this invention is not limited to this and relay of the whole system | system | groups is carried out. -It is also possible to set it as the structure which provided the site | part (diameter reduction part 60) in which the opening diameter of the flow path was reduced, as shown to FIG. 7B in the discharge part flow path RFn. On the contrary, it is also possible to provide a portion (diameter expansion portion) in which each branch flow path Bn is enlarged than a portion having a different flow path diameter. Moreover, as one of the site | part which comprises each branch flow path Bn, the site | part which differs from the site | part which differs in the cross-sectional shape of a flow path can also be provided. In addition, when providing the site | parts which differ from a flow path diameter and cross-sectional shape, such as the diameter reduction part 60 mentioned above, the pressure loss which arises from the fluid flow in each branch flow path Bn, the flow volume of fluid, etc. In order to achieve uniformity, it is preferable to provide a portion such as a diameter reducing portion 60 at the same position in each branch flow path Bn. Moreover, it is preferable that the flow path diameter and flow path cross-sectional area of the site | parts, such as the diameter reduction part 60 provided in each branch flow path Bn, are substantially uniform regardless of the system of the branch flow path Bn. By doing in this way, even if the diameter reduction part 60 is provided, the balance of the pressure loss in each branch flow path Bn, and the flow volume of a fluid can be made more uniform, and in each discharge part Fn, The variation of the discharge amount and discharge pressure of the fluid can be prevented from occurring.

Since the branch flow path structure 50 is formed with each branch flow path Bn by overlapping the grooved flow path forming plates P1 to P4, it is easy and accurate to form the branch flow path Bn designed by the above-described design method. It is possible. In addition, in this embodiment, although the example which comprises each branch flow path Bn is illustrated by overlapping flow path structure plates P1-P4, this invention is not limited to this, A metal pipe | tube, a resin pipe, etc. are suitably bent, etc. By doing so, it is good also as forming the branch flow path Bn mentioned above. Moreover, the branch flow path structure 50 may be comprised by a plurality of types of common parts, and the branch flow path Bn of a desired arrangement | positioning or shape may be formed by combining the said common parts suitably. In addition, the branch flow path structure 50 is formed by forming the parts constituting the flow path SRn between the inlet and relay parts and the parts constituting the relay / discharge pipe path RFn as separate parts, and connecting them to each branch. The flow path Bn may be configured. In addition, for example, the components constituting the lower portion Dnp and the components constituting the horizontal portion Lnq may be separately prepared, and the relay / discharge pipe flow path RFn may be configured by appropriately connecting them.

Since the branch flow path structure 50 shown in the present embodiment is bent at each branch flow path Bn at a position corresponding to the horizontal planes J1 to J3 assumed at the boundary between the respective flow path forming plates P1 to P4, each branch flow path structure 50 is formed at the same height. Although branch flow path Bn was bent, this invention is not limited to this, Each branch flow path Bn is made into a different height, so long as it satisfy | fills the conditions that the total length of each branch flow path Bn becomes equal. It may be curved. When the branch flow paths Bn are bent at different heights, the interference between the branch flow paths Bn can be easily avoided, and the branch flow paths Bn and the discharge portions Fn can be further avoided. It is possible to increase the degree of freedom of the layout.

In this embodiment, although each branch flow path Bn connected to the inlet part S does not branch in the middle, but constitutes a series of flow paths, this invention is not limited to this, and each branch flow path Bn is in the middle. It may be formed so as to further branch into multiple systems. In addition, when branching each branch flow path Bn in the middle, it is preferable to make the branch number the same for each branch flow path Bn. Also, in the case of branching each branch flow path Bn in the middle, the flow path design is performed according to the flow path design method described above to equalize the pressure loss and the flow rate caused by the flow of the fluid, and the fluid in each discharge part Fn. It is possible to equalize the discharge pressure and the discharge amount.

In the branch flow path structure 50 of the present embodiment, since the cross-sectional shape of the inlet portion S is circular, and each branch flow path Bn is connected at substantially equal intervals in the circumferential direction, the inlet portion (from the uniaxial eccentric screw pump 5) The fluid introduced into S) can be supplied substantially uniformly to each branch flow path Bn. In addition, the introduction portion S is not limited to a circular cross-sectional shape, and the cross-sectional shape may be polygonal, but the cross-sectional shape is substantially viewed from the viewpoint of supplying fluid substantially uniformly to each branch flow path Bn. It is preferable that it is a regular n-square or substantially regular n * a square (a is a natural number). Specifically, when three discharge parts Fn are provided, for example, and three branch flow paths Bn are formed, the cross-sectional shape of the introduction part S is as shown in Fig. 8A. It is possible to make an equilateral triangle or to make a regular hexagon (n = 3, a = 2, nxa = 6) as shown in Fig. 8B. By adjusting the shape of the introduction portion S in this way, the fluid introduced into the introduction portion S from the uniaxial eccentric screw pump 5 side can be supplied to each branch flow path Bn almost uniformly.

In the present embodiment, the flow path SRn between the introduction and intermediate portions has only a portion extending in the horizontal direction. However, the present invention may be limited thereto, and the dropping portion Dnp of the flow path RFn between the relay and discharge portions may be limited thereto. Likewise, it may have a portion extending in the vertical direction (vertical direction). Also in this case, the relay section Rn and the inlet section S provided at a position for dividing the circumference of the virtual circle C1 by n are connected in the same manner as described in the aforementioned design method of the branch flow path Bn. By designing the flow path SRn between each introduction / middle part, it becomes possible to supply a fluid substantially uniformly from the introduction part S to each branch flow path Bn.

In the present embodiment, an example in which the uniaxial eccentric screw pump system 1 is configured by combining the branch flow path structure 50 with the uniaxial eccentric screw pump 5 is illustrated, but the present invention is not limited thereto, and the branch flow path structure 50 is not limited thereto. ) May be used in combination with a conventionally known pump other than the uniaxial eccentric screw pump 5, or the like.

1: uniaxial eccentric screw pump system
5: uniaxial eccentric screw pump
50: branching euro construct
60: diameter reduction
Pn: Euro construction plate
S: Introduction
Fn: discharge part
Bn: Quarterly Euro
Rn: relay
SRn: flow path between the inlet and the relay
RFn: Flow between relay and discharge part
Dnp: descent
Lnq: Horizontal part
s: introduction reference point
rn: relay reference point
fn: discharge reference point
H: horizontal plane
V: vertical line

Claims (9)

Branch flow passage structure that can constitute a branch flow path for evenly discharging the fluid introduced from the introduction portion from the n discharge portions,
N relay parts are provided so as to correspond to each of the n discharge parts,
Each quarter euro,
A flow path between an introduction and relay portion of an n-system connecting the introduction portion and the n relay portions,
It has a flow path between the n relay and the discharge portion of the n system connecting the n relay portion and the discharge portion corresponding to the relay portion,
The relay unit is disposed at a position corresponding to n dividing the circumference of the virtual circle centered on one point on the vertical line passing through the axis of the introduction unit,
The branch flow path structure, wherein the length of the flow path between the relay and the discharge portion of the n-system is the same. The branch flow path structure according to claim 1, wherein the relay portion is disposed at a position that substantially divides the circumference of the virtual circle by approximately n. The horizontal portion according to claim 1 or 2, wherein the flow path between the relays and the discharging portions includes a lower portion capable of flowing the fluid downward and a horizontal portion capable of flowing the fluid in the horizontal direction. And a flow path having a bent portion between the lower portion and
The sum total of the length of the said horizontal part with respect to the flow path between each relay and discharge part is the same,
The sum total of the length of the said falling part with respect to the flow path between each relay and discharge part is the same,
A branch flow passage structure, wherein the number of the bent portions in the flow passage between the relay and the discharge portion is the same. The branch flow path structure according to claim 3, wherein a plurality of bent portions are formed in the vertical direction in the flow path between the relays and the discharge parts. The branch flow path structure according to any one of claims 1 to 4, wherein a diameter reduction part in which a flow path diameter is reduced is provided in the flow path between the relay and the discharge part. The branch flow path structure according to any one of claims 1 to 5, wherein the flow path diameter of each branch flow path is substantially uniform regardless of the branch flow path. The branch flow path structure according to any one of claims 1 to 6, wherein the branch flow path structure is formed by overlapping plates on which grooves constituting the branch flow paths are formed. The branch flow path structure according to any one of claims 1 to 7, wherein a cross-sectional shape of the inlet portion is circular or a regular n × a square (a is any natural number). It has the branch flow path structure of any one of Claims 1-8, and the uniaxial eccentric screw pump,
A uniaxial eccentric screw pump system, wherein the fluid discharged from the uniaxial eccentric screw pump can be introduced into an introduction portion of the branch flow path structure.

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