JP5062841B2 - Water meter and inner case for water meter - Google Patents

Description

  The present invention relates to an inner case for a water meter that covers the periphery of an impeller inside a tangential flow impeller-type water meter, and a water meter including the inner case for the water meter.

As a conventional inner case for this type of water meter, for example, a plurality of introduction passages that penetrate the cylindrical inner surface of the water meter inner case in a direction intersecting the radial direction are formed, and the tap water is supplied inside the inner case. A device is known that improves the measurement accuracy by turning and improving the rotational efficiency of the impeller (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 8-105771 ([0014], FIGS. 1 and 2)

  By the way, as for the type approval and verification of water meters, the specific measuring instrument verification inspection rules (regulations) of the Measurement Act were applied. However, due to the amendment of the Ministerial Ordinance in 2005, the inspection regulations are JIS standards (JIS B 8570- 2: 2005), and the acceptance criteria were changed accordingly. For example, with regard to instrumental testing, the test tolerances have been reduced and tests on instrumental water temperature characteristics and instrumental water pressure characteristics have been added. Therefore, it was necessary to develop a highly accurate water meter that suppresses the peak of the instrumental error (the instrumental error increases to the plus side in the minute flow rate range) as much as possible and the linearity of the instrumental error curve.

  This invention is made | formed in view of the said situation, and aims at provision of the water meter which can aim at the further improvement of precision, and its inner case.

  The present inventor has intensively studied to develop a water meter with higher accuracy than before, and has found the following knowledge to complete the present invention. That is, a plurality of introduction projecting walls project from a plurality of circumferential positions in a circle concentric with the rotation trajectory of the impeller to the rear side in the rotation direction of the impeller, and a plurality of introduction projecting walls are adjacent to each other between adjacent introduction projecting walls. In the inner case for a water meter in which a rectangular introduction port is formed, the front edge portion of the rear introduction surface that extends rearward from the rear opening edge in the rotation direction of the impeller at the rectangular introduction port, out of the introduction projection wall In addition, the present invention has been completed which can further improve the accuracy by forming the leading end flat surface rising outward from the inner circular arc surface. The present invention provides the following inner case for water meter and water meter.

  An inner case for a water meter according to the invention of claim 1 made to achieve the above object has a bottomed bottom cylindrical structure covering an impeller rotating in one direction inside a tangential flow impeller water meter. In addition, between a plurality of introduction protrusion walls projecting from a plurality of positions in the circumferential direction in a circle concentric with the rotation locus circle of the impeller to the rear side in the rotation direction of the impeller, and between adjacent introduction protrusion walls An inner case for a water meter that has a plurality of rectangular inlets formed and that can guide tap water through the inlet protrusion wall, introduce it into the interior from the rectangular inlet, and allow the water to swivel. On the wall, an inner circular arc surface arranged on a circle concentric with the rotation locus circle of the impeller, and a rear introduction extending rearward in the rotation direction from the rear opening edge of the impeller in the rotation direction of the impeller Surface and rear opening edge from the front opening edge of the rectangular inlet In the inner case for a water meter in which the front introduction surface is formed, the entire portion excluding the front edge portion of the rear introduction surface is a flat surface, and the front edge portion of the rear introduction surface extends from the flat surface to the front end. Asymptotic surface gradually approaching the inner arc surface side from the front side to the front side, and an introduction tip plane that rises outward from the inner arc surface and intersects the front end of the asymptotic surface at an angle of 90 ° to 130 ° is formed It has the characteristics.

  In addition, the “one direction” of “the impeller rotating in one direction” in claim 1 of the present application means the rotation direction during normal use of the water supply (a state where the faucet is opened). In addition, the impeller can rotate in the direction opposite to "one direction" accidentally (for example, when the faucet is sharply closed) when water is not used (the faucet is closed) Is not to be excluded.

  According to a second aspect of the present invention, in the inner case for a water meter according to the first aspect, the distance from the intersection of the extension line from the asymptotic surface to the front and the inner arc surface to the introduction tip plane is 0.165-0. It has a feature at 437 mm.

  According to a third aspect of the present invention, in the inner case for a water meter according to the first or second aspect, the gap between the inner arc surface and the tip of the blade provided on the impeller is 2. It is characterized by being configured to be 2% or less.

  A water meter according to a fourth aspect of the invention includes the water meter inner case according to any one of the first to third aspects, and an impeller that is housed in the water meter inner case and rotates according to the flow rate. However, it has characteristics.

  According to the present invention configured as described above, the peak of the instrumental difference curve can be reduced and the linearity of the instrumental difference curve can be improved as compared with the conventional one. Thereby, the further improvement of the accuracy of a water meter is attained.

  Further, when the distance from the intersection of the extension line from the asymptotic surface to the front and the inner arc surface to the introduction tip plane is 0.165 to 0.437 mm as in the invention of claim 2, the water temperature is 10 ° C to 30 ° C. In the range of ° C, the instrumental error can be kept within the test tolerance.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
The water meter 10 of the present embodiment shown in FIG. 1 is a so-called “tangential flow impeller type” water meter, in which an impeller 30 and a water meter inner case 40 (hereinafter, simply “ Inner case 40 ") is accommodated. The meter case 11 is formed by assembling an upper casting case 13 on the upper end surface of the lower casting case 12. The lower casting case 12 has a structure in which a pair of connecting pipes 15 and 15 are extended in opposite directions from the outer peripheral surface of the cylindrical portion 14 with the upper end open, and these connecting pipes 15 and 15 are connected to a water pipe (not shown). Is done. The front end opening of the left connection pipe 15 in FIG. 1 forms the inflow port 15A, while the front end opening of the opposite connection pipe 15 forms the outflow port 15B. The casting lower case 12 is a so-called “double box type (20 mm)”, and the inside thereof includes a lower chamber 17 extending downward from the inflow port 15A, and an upper chamber 16 positioned above the lower chamber 17. It is divided into. The upper chamber 16 and the lower chamber 17 overlap with each other in the cylindrical portion 14 and communicate with each other through a communication port 18. Of the meter case 11 of the present embodiment, the main dimensions of the lower casting case 12 conform to the “double box type 20 mm water meter” shown in “Appendix A” of JIS B 8570-1: 2005. It has become.

  An open port is formed at the upper end of the cylindrical portion 14, from which the inner case 40 and the unit case 20 are inserted and assembled. The impeller 30 is accommodated in the inner case 40, and the impeller 30 rotates according to the flow rate flowing through the inner case 40. A stepped portion 42 is provided in the middle of the outer circumferential surface of the inner case 40 in the axial direction, and the stepped portion 42 is pressed against the edge of the communication port 18 in the meter case 11 from above. Further, the unit case 20 is assembled over the inner case 40 above the impeller 30. The inside of the unit case 20 is a waterproof room, and an integration display unit (not shown) is accommodated here.

  The total display unit counts and displays the total flow of tap water. And if the upper surface lid | cover 13F with which the casting upper case 13 was equipped is opened, the display of an integrating | accumulating display unit can be seen through the glass window provided in the upper wall of the casting upper case 13. FIG.

  The impeller 30 is made of synthetic resin, and includes a plurality of blades 32 that are formed so as to protrude from the outer peripheral surface of a shaft 31 that extends in the vertical direction, as shown in FIG. As shown in FIG. 3A, the plurality of blades 32 extend straight from the position where the shafts 31 are arranged in the circumferential direction in a uniform manner, as shown in FIG.

  As shown in FIG. 1, a hollow having a lower end is formed in the core portion of the shaft 31, and a bearing 34 for reducing friction with a pin 44 to be described later is fitted in the inner portion thereof. . The impeller 30 floats from the bottom wall 43 of the inner case 40 with the pin 44 abutting against the bearing 34.

  A magnet 35M is fixed to the upper end of the shaft 31. The integration display unit is provided with a magnetic sensor (not shown) at a position facing the magnet 35M, and the rotation of the impeller 30 is detected by this magnetic sensor.

  The inner case 40 is a molded product made of a synthetic resin and has a bottomed bottomed cylindrical structure covering the periphery of the impeller 30 as shown in FIGS. 1 and 3A.

  As shown in FIG. 5, an opening 41B is provided at the upper end of the inner case 40, and the impeller 30 is inserted from the opening 41B. In addition, the step portion 42 is formed in the axially intermediate portion of the outer peripheral surface of the inner case 40, and the outer diameter of the upper portion of the step portion 42 is larger than the lower portion (FIG. 6). reference).

  As shown in FIG. 5, an embossed portion 43E is provided in the center on the inner surface of the bottom wall 43 that closes the lower end of the inner case 40, and a plurality of ribs 43L extend radially from the embossed portion 43E. A pin through hole 48 is formed in the center of the embossed portion 43E, and a metal pin 44 is inserted through the pin through hole 48 (see FIG. 1). In addition, a metal plate for retaining 44K is locked to a lower end portion of the pin 44 that penetrates the embossed portion 43E.

  The inner case 40 includes a cylindrical inner surface 41A (corresponding to an “inner circular arc surface” according to the present invention) having a diameter R1 with the pin 44 (pin through hole 48) as the center, and the inner cylindrical surface 41A and an impeller A gap (gap) 45 having a predetermined dimension L1 is formed between the leading edges of the 30 blades 32 (see FIG. 3B). As will be described later, the dimension L1 of the gap 45 is preferably 2.2% or less of the diameter R1 (for example, 47.4 mm in the present embodiment) of the cylindrical inner surface 41A.

  As shown in FIGS. 5 and 6, discharge holes 46 are formed in the inner case 40 on the upper side of the stepped portion 42 at positions equally spaced in the circumferential direction. The discharge hole 46 penetrates the peripheral wall of the inner case 40 in a direction (substantially tangential direction) that obliquely intersects the radial direction (see FIG. 7). As shown in FIG. 1, the discharge hole 46 communicates with the upper chamber 16 of the meter case 11, and the water in the inner case 40 is discharged to the upper chamber 16.

  As shown in FIG. 6, introduction nozzles 47 are formed at a plurality of positions in the circumferential direction (specifically, eight positions in the circumferential direction) below the stepped portion 42 in the inner case 40. Each introduction nozzle 47 communicates with the lower chamber 17 of the meter case 11 and takes in the water flowing into the lower chamber 17 into the inner case 40 so that the impeller 30 moves in one direction (for example, FIG. 3A). In the counterclockwise direction in FIG. 9 and the counterclockwise direction in FIG. 9).

  Specifically, the introduction projecting wall 50 protrudes from a plurality of circumferential positions (positions equally spaced in the circumferential direction) on the cylindrical inner surface 41 </ b> A toward the rear side in the rotational direction of the impeller 30. An introduction nozzle 47 is formed between the combined introduction protrusions 50 and 50. In addition, a rectangular introduction port 47A is formed between the adjacent introduction projecting walls 50, 50. The rectangular introduction ports 47A are eight in total, and are arranged at equal intervals in the circumferential direction of the cylindrical inner surface 41A.

  Each introduction projection wall 50 has a front opening edge 47A1 in the rotational direction of the impeller 30 among the opening edges of each rectangular introduction opening 47A (for example, the right opening edge toward the rectangular introduction opening 47A from the outside, see FIG. 9). ) To project outward so as to cover each of the rectangular inlets 47A.

  As shown in FIGS. 4 and 6, the upper surface 47B of each introduction nozzle 47 has an inclined surface 47B1 lowered as it approaches the rectangular introduction port 47A, and between the inclined surface 47B1 and the upper edge of the rectangular introduction port 47A. It is comprised from the communicated horizontal surface 47B2. Each introduction nozzle 47 is open downward. That is, the introduction nozzle 47 has a structure in which three sides other than the lower side are closed.

  By the way, as shown in FIGS. 3 to 6, each introduction projecting wall 50 has a rear opening edge 47 </ b> A <b> 2 in the rotation direction of the impeller 30 at the rectangular introduction port 47 </ b> A (on the left side toward the rectangular introduction port 47 </ b> A from the outside). A rear introduction surface 51 extending rearward in the rotation direction from the opening edge) and a front introduction surface 52 extending rearward in the rotation direction from the front opening edge 47A1 in the rectangular introduction port 47A are formed. The front introduction surface 52 faces the rectangular introduction port 52 from the side, and from the side to the front side portion of the rear introduction surface of the adjacent introduction projection wall 50 extending from the rear opening edge 47A2 of the rectangular introduction port 52. Opposite (see FIG. 10).

  The introduction nozzle 47 is formed between the front introduction surface 52 and the rear introduction surface 51 arranged before and after the rectangular introduction port 47A, and passes through the introduction nozzle 47 from the rectangular introduction port 47A to the inner case 40. The water that has flowed into the water turns in one direction within the inner case 40. Thereby, the impeller 30 rotates in the one direction.

  The front introduction surface 52 of the introduction projection wall 50 is configured by a plane parallel to the axial direction of the inner case 40 (direction perpendicular to the paper surface of FIG. 9). The front introduction surface 52 intersects the tangent of the cylindrical inner surface 41A at the intersection with the cylindrical inner surface 41A at a predetermined intersection angle θ1 (about 18 ° in the present embodiment) (see FIG. 9).

  On the other hand, the rear introduction surface 51 of the introduction projection wall 50 is configured by a plane that is not parallel to the front introduction surface 52. As shown in FIG. 11, the rear introduction surface 51 is provided on a flat surface 51 </ b> A extending from the outer peripheral surface of the inner case 40 to a position near the rectangular introduction port 47 </ b> A and a front edge portion of the rear introduction surface 51. An asymptotic surface 51B gradually approaching the cylindrical inner surface 41A as it goes from the front end of the flat surface 51A to the front side. Both the flat surface 51A and the asymptotic surface 51B are planes parallel to the axial direction of the inner case 40 (direction orthogonal to the paper surface of FIG. 11). Here, in the present embodiment, the bending angle between the flat surface 51A and the asymptotic surface 51B is about 158 °. Further, an intersection angle θ2 between the extension line S1 extending forward from the asymptotic surface 51B and the tangent line S2 at the intersection P1 where the extension line S1 intersects the cylindrical inner surface 41A is set to about 20 °. As shown in FIG. 12, the flat surface 51A of the rear introduction surface 51 is configured to circumscribe a concentric circle R2 having a larger diameter than the cylindrical inner surface 41A. For example, when the diameter R1 of the cylindrical inner surface 41A is 47.4 mm, the diameter of the concentric circle R2 is about 48.9 mm. Further, an extension line extending forward from the front introduction surface 52 is configured to circumscribe a concentric circle R3 having a smaller diameter than the cylindrical inner surface 41A. For example, when the diameter R1 of the cylindrical inner surface 41A is 47.4 mm, the diameter of the concentric circle R3 is about 45.4 mm. An introduction tip flat surface 53 of the present invention is formed on the front edge portion of the rear introduction surface 51 so as to be continuous with the asymptotic surface 51B.

  As shown in FIG. 11, the introduction tip flat surface 53 is configured by a plane parallel to the axial direction of the inner case 40. The introduction tip flat surface 53 rises outward from the cylindrical inner surface 41A and intersects the front end of the asymptotic surface 51B, and constitutes a rear opening edge 47A2 of the rectangular introduction port 47A. The leading end flat surface 53 has a distance W (hereinafter referred to as “offset distance”) from the intersection P1 where the extension line S1 extending forward of the asymptotic surface 51B intersects the arc including the cylindrical inner surface 41A in the rotational direction of the impeller 30. It intersects the cylindrical inner surface 41A at a position shifted by “W”) and intersects the asymptotic surface 51B substantially at a right angle. Thereby, the front edge part of the rear side introduction surface 51 has a triangular (sawtooth) shape.

Next, the operation of the present embodiment configured as described above will be described.
When the water meter 10 is connected in the middle of a water pipe (not shown), tap water that has passed through one of the connecting pipes 15 flows into the lower chamber 17 and is introduced into the inner case 40 and a rectangular introduction. It flows into the inner case 40 through the opening 47A. At this time, the tap water is guided in the substantially tangential direction of the cylindrical inner surface 41 by the introduction protruding wall 50 and flows into the inner case 40. Accordingly, the tap water turns upward while turning in the inner case 40. Then, it flows out from the inner case 40 to the upper chamber 16 through the discharge hole 46 and is discharged to the other connecting pipe 15.

  The impeller 30 accommodated in the inner case 40 receives tap water turning in the inner case 40 and rotates in the turning direction. The rotation of the impeller 30 is transmitted to the integration display unit via the magnet coupling, and thereby the flow rate of tap water is measured.

[Experiment 1]
The following experiment was conducted in order to examine the effect of the “introducing tip plane 53” according to the present invention. The experimental method is as follows.

[experimental method]
A water meter 10 as an embodiment of the present invention having the same structure as that of the above embodiment and a conventional water meter (hereinafter referred to as “conventional product 1” as appropriate) that does not include the introduction tip plane 53 were manufactured. As a water meter which is an implementation product of the present invention, an offset distance W (see FIG. 11) of the introduction tip plane 53 is set to 0.25 mm (hereinafter referred to as “execution product 1”), and 0.375 mm. (Hereinafter referred to as “Practical Product 2”) and 0.5 mm (hereinafter referred to as “Practical Product 3”). Note that the dimension L1 of the gap 45 was the same (1.25 mm) in the products 1, 2, 3 and the conventional product 1.

Next, for each of these water meters (implemented products 1, 2, 3 and conventional product 1), the test method (JIS B 8570-2: 2005 “ 7.2 Instrument error test ”). Specifically, water was passed at a preset flow rate, and the measured value (display value of the water meter) at that time was obtained. Incidentally, the rated maximum flow rate Q3 was set to ^4m 3 / h, limit the flow rate Q4 is ^{5 m} 3 / h, the rated minimum flow rate Q1 is 0.04 m ³ / h, transition flow Q2 is 0.064 m ³ / h. The test water temperature was 20 ° C.

  And the instrumental difference of each water meter (implemented product 1, 2, 3 and the conventional product 1) was calculated for every set flow rate, and was made into a graph (instrumental difference curve) as shown in FIG. In this graph, the test tolerance (allowable value of instrumental error) is indicated by a thick line.

[Experimental result]
Comparing the products 1, 2 and 3 with the conventional product 1 based on the graph of FIG. 13A, in the products 1, 2 and 3, the difference between the rated minimum flow rate Q1 and the limit flow rate Q4 is It was found that the width between the maximum value and the minimum value was smaller than that of the conventional product 1, and the linearity of the instrumental difference curve was improved. In addition, in the product 1 (offset distance W is 0.25 mm) and the product 2 (offset distance W is 0.375 mm), the instrumental error is verified across the entire range from the rated minimum flow rate Q1 to the limit flow rate Q4. Was able to be inside.

[Experiment 2]
Next, the following experiment was conducted to examine the effect of the dimension L1 of the gap 45 between the tip edge of the blade 32 of the impeller 30 and the cylindrical inner surface 41A. The experimental method is as follows.

[experimental method]
Water meters (improved products 1 and 2 and conventional product 2) in which the diameter R1 of the cylindrical inner surface 41A and the dimension L1 of the gap 45 are set as shown in Table 1 below were manufactured. In Experiment 2, in order to eliminate the influence of the introduction tip flat surface 53 described above, the introduction tip flat surface 53 was not provided in the inner case of any water meter.

  Next, water was passed through each water meter (improved products 1 and 2 and conventional product 2) under the same conditions as in Experiment 1 above, and the measured value (displayed value of the water meter) at that time was determined. And the instrumental difference of each water meter was computed for every setting flow volume, and it was made into the graph (instrumental difference curve) as shown in FIG.13 (B).

[Experimental result]
Comparing the improved products 1 and 2 with the conventional product 2 based on the graph of FIG. 13 (B), the improved products 1 and 2 have a smaller instrumental difference peak in the fine flow rate region than the conventional product 2, and the medium flow rate. It was found that the sag of the instrumental error in the region (increase of instrumental error to the minus side) is suppressed and the linearity is improved. Moreover, it turned out that the peak of the instrumental difference curve becomes smaller in the improved product 1 in which the dimension L1 of the gap 45 is smaller than that in the improved product 2. That is, it has been found that by setting the dimension L1 of the gap 45 to 2.2% or less of the diameter R1 of the cylindrical inner surface 41A, the peak of the instrumental error curve becomes smaller than before and the linearity is improved.

[Experiment 3]
Next, based on the results of Experiment 1 and Experiment 2, the product of the present invention was manufactured with specifications that seem to be optimal, and the test method (JIS B 8570- 2: The water temperature test was conducted according to “7.2.8 Water temperature test” of 2005).

  In addition, the specified meter verification inspection rules stipulate that the acceptance standard for the transfer flow rate Q2 not to deviate (within ± 2%) is the acceptance criterion. The instrumental difference of each temperature was measured in the range from the flow rate smaller than Q1 to the limit flow rate Q4. The specific experimental method is as follows.

[experimental method]
As a water meter that is an embodiment of the present invention, the diameter R1 of the cylindrical inner surface 41A of the inner case 40 is 47.4 mm, the offset distance W (see FIG. 11) is 0.375 mm, and the dimension L1 of the gap 45 is 1.0 mm (diameter). R1 (2.11%) was manufactured (hereinafter referred to as “Example 4”).

Next, water was passed through the water meter of the implementation product 4 and the conventional product 2 at a preset water temperature and a preset flow rate, and the measured value (display value of the water meter) at that time was obtained. The test water temperature was set to 10 ° C., 20 ° C., and 30 ° C. assuming a water temperature class T30 of a general water meter (maximum allowable use temperature is 30 ° C.). Also, the rated maximum flow rate Q3 was set to ^4m 3 / h, limit the flow rate Q4 is ^{5 m} 3 / h, the rated minimum flow rate Q1 is 0.04 m ³ / h, transition flow Q2 is 0.064 m ³ / h.

  And the instrumental difference of each water meter (implemented product 4 and conventional product 2) is calculated for each set flow rate, and the instrumental difference of each water meter is graphed (tester difference curve) according to the test water temperature as shown in FIG. did.

[Experimental result]
As shown in the graph of FIG. 14A, in the conventional product 2, when the test water temperature is 20 ° C. and 30 ° C., the instrumental error is within the verification tolerance over the entire range from the rated minimum flow rate Q1 to the limit flow rate Q4. Fell into. However, it was found that when the test water temperature is 10 ° C., the instrumental error peak shifts to the transition flow rate Q2 side and deviates from the verification tolerance at the transition flow rate Q2. Moreover, in the conventional product 2, slack in the instrumental difference occurred in the middle flow rate region at any water temperature.

  On the other hand, as shown in the graph of FIG. 14B, in the implementation product 4, the instrumental error is within the verification tolerance over the entire range from the rated minimum flow rate Q1 to the limit flow rate Q4 at any test water temperature. I found it fit. In addition, it was found that the practical product 4 had a smaller instrumental curve peak than the conventional product 2, and almost no sag in the middle flow rate region, and improved linearity. In the product 4 as well, it was found that when the test water temperature was 10 ° C., the peak of the instrumental difference shifted to the transition flow rate Q2 side.

  Incidentally, as is clear from the experimental results of the experiment 1 (the graph shown in FIG. 13A), when the test water temperature is made constant, the offset distance W of the introduction tip plane 53 increases from the micro flow region. It was found that the instrumental difference between the midstream regions became larger on the minus side, and when the offset distance W was set to 0.5 mm, it deviated from the verification tolerance in the transition flow rate Q2. As is clear from the experimental results of the experiment 3 (the graph shown in FIG. 14B), when the offset distance W of the introduction tip plane 53 is constant, the peak of the instrumental difference curve when the test water temperature is 10 ° C. Was found to shift to the transition flow rate Q2 side than when the test water temperature was 20 ° C and 30 ° C. From these facts, it can be said that whether or not the instrumental error in the transfer flow rate Q2 falls within the verification tolerance is one measure of whether or not the water meter passes the instrumental test.

[Experiment 4]
Therefore, the following experiment was conducted to examine the relationship between the test water temperature and the offset distance W at the transition flow rate Q2. The experimental procedure is as follows.

[experimental method]
Using the above-mentioned products 1, 2, 3 and the conventional product 1, the same experiment as the above-mentioned experiment 1 was performed by changing the test water temperature to 10 ° C. And the relationship between the instrumental difference and the offset distance W in the transition flow rate Q2 is a linear relational expression by the least square method. A graph of this relational expression is shown in FIG. In the graph, the horizontal axis is the offset distance W, and the vertical axis is the instrumental difference in the transfer flow rate Q2.

  Similarly, the relationship between the instrumental difference and the offset distance W in the transition flow rate Q2 obtained in the experiment 1 (test water temperature 20 ° C.) is a linear relational expression by the least square method. A graph of this relational expression is shown in FIG. In the graph, the horizontal axis is the offset distance, and the vertical axis is the instrumental difference in the transfer flow rate Q2.

[Experimental result]
The relational expression between the instrumental difference in the transition flow rate Q2 and the offset distance W when the test water temperature is 10 ° C. is
Instrumental error (%) = − 9.6571 · W + 3.5986
It became. From this relational expression, it was found that when the test water temperature is 10 ° C., the offset distance W that satisfies ± 2% or less, which is the test tolerance in the transition flow rate Q2, is 0.165 mm to 0.580 mm.

On the other hand, the relational expression between the instrumental difference and the offset distance W in the transition flow rate Q2 when the test water temperature is 20 ° C. is
Instrumental error (%) = -7.5269 · W + 1.2894
It became. From this relational expression, it was found that when the test water temperature is 20 ° C., the offset distance W that satisfies ± 2% or less, which is the test tolerance in the transition flow rate Q2, is 0 to 0.437 mm. As shown in the graph of FIG. 14, since the instrumental difference in the transition flow rate Q2 is almost the same at the test water temperature of 20 ° C. and 30 ° C., it is estimated that the test water temperature of 30 ° C. is almost the same as the test water temperature of 20 ° C. Is done.

  From the above, when the introduction tip flat surface 53 is provided in the inner case 40 having the diameter R1 of the cylindrical inner surface 41A of 47.4 mm, the offset distance W is 0.165 mm to 0.437 mm, more preferably 0.2 mm to If it is set to 0.4 mm, it is estimated that the instrumental difference in the transition flow rate Q2 can be within the verification tolerance within the range of the water temperature of 10 ° C to 30 ° C.

[Other Embodiments]
The present invention is not limited to the above-described embodiment. For example, the embodiments described below are also included in the technical scope of the present invention, and various other than the following can be made without departing from the scope of the invention. It can be changed and implemented.

  (1) Only the leading end flat surface 53 is provided, and the dimension L1 of the gap 45 may be 2.2% or more of the diameter R1 of the cylindrical inner surface 41A as usual.

  (2) In the above embodiment, the asymptotic surface 51B is a flat surface, but it may be an arcuate surface that is continuous with the flat surface 51A. In addition, the leading end surface 53 intersects the asymptotic surface 51B at a substantially right angle, but may be substantially parallel to the radial direction of the cylindrical inner surface 41A. In this case, the leading end surface 53 and the asymptotic surface 51B may intersect at an obtuse angle (for example, a range of 90 ° to 130 °) (see FIG. 16).

Partial sectional drawing of the water meter which concerns on one Embodiment of this invention Side view of the inner case containing the impeller (A) A-A 'sectional view in FIG. 2, (B) Partial enlarged view thereof Side view of inner case Perspective view of the inner case as seen from above Perspective view of the inner case as seen from below Top view of the inner case Bottom view of inner case A-A 'sectional view in FIG. B-B 'sectional view in FIG. CD partial enlarged view in FIG. A-A 'cross-sectional partial enlarged view in FIG. (A) Graph showing the experimental results of Experiment 1, (B) Graph showing the experimental results of Experiment 2 (A) A graph showing the experimental result of the conventional product 2 according to Experiment 3, and (B) a graph showing the experimental result of the implementation product 4 according to Experiment 3. (A) A graph showing experimental results when the test water temperature is 10 ° C. according to Experiment 4, and (B) A graph showing experimental results when the test water temperature is 20 ° C. according to Experiment 4. The expanded sectional view of the front end part of the introduction protrusion wall concerning a modification

Explanation of symbols

10 Water Meter 11 Meter Case 30 Impeller 32 Blade 40 Inner Case (Inner Case for Water Meter)
41A Cylindrical inner surface (inner arc surface)
45 gap 47 introduction flow path 47A rectangular introduction port 47A1 front opening edge 47A2 rear opening edge 50 introduction protrusion wall 51 rear introduction surface 51A flat surface 51B asymptotic surface 52 front introduction surface 53 introduction tip plane L1 clearance dimension R1 of cylinder inner surface Diameter (Inner arc surface diameter)
W Offset distance

Claims (4)

A tangential flow impeller-type water meter has a bottom-bottomed cylindrical structure that covers an impeller that rotates in one direction, and the blades from a plurality of circumferential positions on a circle concentric with the rotation locus circle of the impeller A plurality of introduction projecting walls projecting to the rear side in the rotation direction of the vehicle, and a plurality of rectangular introduction ports formed between the adjacent introduction projecting walls, and tap water is introduced into the introduction projecting wall. It is an inner case for a water meter that can be guided by and introduced into the inside from the rectangular introduction port and swiveled,
Each introduction protrusion wall has an inner circular arc surface arranged on a circle concentric with the rotation locus circle of the impeller, and a rotation direction from a rear opening edge of the rectangular introduction port in the rotation direction of the impeller. In the water meter inner case formed with a rear introduction surface extending rearward and a front introduction surface extending rearward in the rotational direction from a front opening edge of the rectangular introduction port,
The whole excluding the front edge of the rear side introduction surface is a flat surface,
An asymptotic surface gradually approaching the inner arc surface side from the flat surface toward the front side from the front surface to the front edge portion of the rear introduction surface, and rises outward from the inner arc surface to the front end of the asymptotic surface And an introduction tip plane intersecting at an angle of 90 ° to 130 ° is formed.   2. The water meter according to claim 1, wherein a distance from an intersection of the asymptotic surface to the front and the inner arc surface to the introduction tip plane is 0.165 to 0.437 mm. Inner case.   The gap between the inner arc surface and the tip of a blade provided in the impeller is configured to be 2.2% or less of the diameter of the inner arc surface. An inner case for a water meter as described in 1. An inner case for a water meter according to any one of claims 1 to 3,
A water meter comprising: an impeller housed in the water meter inner case and rotating according to a flow rate.

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