KR200456406Y1 - Water meter - Google Patents

Abstract

The present invention relates to a water meter that is capable of measuring accurate flow rates by blocking foreign substances from entering the upper inner shell. The opening proposal is installed in the lower inner shell open to the upper, the upper inner shell of the lower inner shell is formed through the rotating shaft through-hole in the center of the bottom surface, the upper inner shell formed by radially projecting a plurality of resistance plates on the bottom and rotatably installed in the lower inner shell In a water meter including a vane assembly coupled to the center of the van and the van and consisting of a rotating shaft passing through the rotating shaft through hole, the center of the bottom of the upper inner shell is connected to the rotating shaft through hole to penetrate the rotating shaft to be lower than the resistance plate A protruding boss portion is formed, and a boss portion insertion groove into which the boss portion is inserted is formed in an upper center portion of the vane. Therefore, not only the amount of water flowing into the upper inner shell is reduced, but foreign matters are also blocked into the upper inner shell, thereby preventing malfunction of the counting device and enabling accurate measurement of the flow rate.

Description

Water Meter {WATER METER}

The present invention relates to a water meter, and more particularly, to a water meter that is capable of measuring accurate flow rates by blocking foreign substances from entering the upper inner bag.

In general, the water meter is to accurately measure the flow rate of the constant water supplied to the user, such as home or factory, to measure the amount of water supplied for a certain period of time, and is installed separately in the water supply line connected to the user side.

The water meter includes a positive displacement type water meter and a current type water meter. Actual water meters are used mainly for testing by measuring water in a volume. The speculative water meter is an indirect method of measuring the actual flow rate depending on the flow rate or the rotational speed of the blade car.

The speculative water meter has a multi-jet type water meter, which flows through the inlet of the lower outer shell and rotates the vane through several sorting holes in the lower inner shell. Wet systems are submerged and dry systems do not flow into the scale plate.

Generally, the wet water meter is installed in the lower outer shell connected to the water supply line, the upper outer shell installed at the upper portion of the lower outer shell, and the cap is installed at the open upper portion, and installed in the lower inner shell so that all the water flowing through the lower outer shell passes. A lower inner shell, an upper inner shell installed at an upper portion of the lower inner shell to seal an open upper portion of the lower inner shell, a vane assembly rotatably installed in the lower inner shell to rotate in proportion to the flow rate of water flowing into the lower inner shell, and an upper portion of the lower inner shell. It is installed on the upper part of the head and includes a counting device that operates in accordance with the rotation of the blade assembly.

Hereinafter, the lower inner shell, the upper inner shell and the blade assembly of the components of the wet water meter according to the prior art having the configuration as described above will be described in detail.

1 is a perspective view of a lower inner shell, an upper inner shell and a vehicle body assembly of a wet water meter according to the prior art, and FIG. 2 is a cross-sectional view showing a state in which the lower inner shell, the upper inner shell and the vehicle body assembly of FIG. 3 is a cross-sectional view showing a state in which the lower inner shell, the upper inner shell and the blade assembly of FIG.

A plurality of inlet holes 11 through which constant is introduced is formed in the lower outer periphery of the lower inner shell 10, and a plurality of outlet holes 12 are formed in the upper outer periphery. At the center of the inner bottom surface of the lower inner shell 10, a support shaft 13 for rotatably supporting the blade assembly 30 is provided.

The upper inner shell 20 is installed on the open upper portion of the lower inner shell 10 to seal the lower inner shell 10, it is formed to open to the upper. In the center of the bottom surface of the upper inner shell 20, a rotating shaft through hole 21 through which the rotating shaft 32 of the blade assembly 30 will be formed is formed, and the lower surface of the upper inner shell 20 has a rotation shaft through hole 21. A plurality of resistance plates 22 protrude radially around.

The vane assembly 30 includes a vane 31 installed at the lower inner shell 10 to rotate, and a rotation shaft 32 integrally coupled to the center of the vane 31. The rotating shaft 32 passes through the rotating shaft through-hole 21 of the upper inner shell 20, and its tip is coupled to interlock with the counting device.

At this time, a support shaft insertion groove 33 into which the support shaft 13 is inserted is formed in the lower portion of the blade wheel 31, and the periphery of the blade wheel 31 is introduced into the lower inner shell 10 through the upper and lower portions of the blade wheel 31. Water flow hole 34 is formed through which the water flows into the upper inner bag 20 through the lower portion of the blade car 31.

According to the conventional wet water meter configured as described above, the water flowing through the inlet of the lower outer shell is discharged to the outside through the outlet of the lower outer shell after passing through the lower inner shell 10. In this process, the blade wheel 31 of the blade assembly 30 is rotated in proportion to the flow rate of the water flowing into the lower inner shell 10 and the counting device is operated in conjunction with the blade wheel 31.

However, according to the conventional wet water meter as described above, a gap is formed between the rotary shaft 32 and the rotary shaft through hole 21 of the vane assembly 30, and water flows into the upper inner shell 20 through the gap. In the process, foreign matter contained in the water is also introduced into the upper inner shell 20. As such, when foreign matter is introduced into the upper inner shell 20, the foreign matter affects the operation of the counter, and there is a problem in that it is difficult to accurately measure the flow rate.

An object of the present invention is to solve the above-mentioned problems, and to block the inflow of foreign matter into the upper inner bag, to prevent the malfunction of the counting device to provide a water meter to enable accurate flow rate measurement.

In order to achieve the above object, the water meter of the present invention is provided with a lower inner shell open to the upper side, an upper upper shell formed at an open upper portion of the lower inner shell, a rotating shaft through-hole is formed at the center of the bottom surface, and a plurality of resistance plates protrude radially from the bottom surface. And a vane assembly rotatably installed in the lower inner shell and the vane assembly coupled to the center of the vane and having a rotating shaft passing through the rotating shaft through hole, wherein the center of the bottom of the upper inner shell is connected to the rotating shaft through hole. A boss portion protruding downwardly from the resistance plate through the rotating shaft is formed, and a boss portion insertion groove into which the boss portion is inserted is formed in the upper center portion of the vane.

A protrusion is formed at the center of the inner bottom of the lower inner shell, and a protrusion insertion groove into which the protrusion is inserted is formed at the lower center of the vane.

A flowing communication hole is formed in the center of the blade car so as to allow the flow of running water, and the boss portion insertion groove and the protrusion insertion groove are connected through the flowing communication hole.

According to the water meter according to the present invention, the boss portion protruding in the center of the bottom surface of the upper inner shell is inserted into the boss portion insertion groove formed in the upper blade of the vehicle assembly, thereby increasing the contact area between the upper shell and the blade assembly. In addition, the protrusion formed at the center of the inner bottom surface of the lower inner shell is inserted into the protrusion insertion groove formed at the lower portion of the blade assembly of the blade assembly, thereby increasing the contact area between the lower shell and the blade assembly. Therefore, not only the amount of water flowing into the upper inner shell is reduced, but foreign matters are also blocked into the upper inner shell, thereby preventing malfunction of the counting device and enabling accurate measurement of the flow rate.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a cross-sectional view showing a water meter according to an embodiment of the present invention.

Water meter according to the present invention, as shown in Figure 4, the lower outer shell 100, the upper outer shell 200, lower inner shell 300, upper inner shell 400, vane assembly 500 and the counting device 600 )

The lower outer shell 100 has an inlet 110 and outlet 120 is connected to the water supply line. Inlet 110 is provided with a strainer 130 to prevent foreign substances contained in the water supply supplied through the water supply line to be introduced into the water meter. In the interior of the lower outer shell 100, a vertical hole 140 that is substantially perpendicular to a virtual connection line connecting the inlet 110 and the outlet 120 is formed. Water introduced through the inlet 110 is changed in a substantially vertical direction while passing through the vertical hole 140.

The upper outer shell 200 is installed on the upper upper outer shell 100, it is to seal the inside of the water meter with the lower outer shell (100). The upper outer shell 200 is opened to the upper portion, the cap 210 is installed to open and close the upper portion.

The lower inner shell 300 is installed through the vertical hole 140 in the lower outer shell 100 so that the water flowing through the lower outer shell 100 is introduced through the lower portion of the lower outer shell 100 and then again through the upper portion. It is configured to be discharged to the lower outer shell 100, the blade wheel 510 of the blade assembly 500 to be described later is rotated therein.

The upper inner shell 400 is installed on the lower inner shell 300 to seal the open upper portion of the lower inner shell 300. The counting device 600 is installed on the inner upper portion of the upper inner shell 400.

The vane assembly 500 is rotatably installed in the lower inner shell 300, and rotates in proportion to the flow rate of water introduced into the lower inner shell 300.

The counting device 600 is driven by the rotation of the vane assembly 500, and includes a plurality of gears 610, a counting unit 620, and a transparent plate 630. The transparent plate 630 is installed to be exposed to the open upper portion of the upper outer shell 200.

5 is a perspective view of the lower inner shell, upper inner shell and the blade assembly of Figure 4 is separated, Figure 6 is a cross-sectional view of the lower inner shell, upper inner shell and the blade assembly of Figure 4 is separated, Figure 7 Sectional view of the lower inner shell, upper inner shell and the blade assembly combined.

A plurality of inlet holes 310 through which water is introduced is formed in the lower outer periphery of the lower inner shell 300, and a plurality of discharge holes 320 are formed in the upper outer periphery. The inlet hole 310 is located below the vertical hole 140 of the lower outer shell 100 and the discharge hole 320 is located above the vertical hole 140. Therefore, the water flowing through the inlet 110 of the lower outer shell 100 is introduced into the lower inner shell 300 through the inlet hole 310 at the bottom of the vertical hole 140 and then vertically through the discharge hole 320. After discharged to the upper portion of the hole 140 is discharged to the outside through the outlet 120 of the lower outer shell (100).

A protrusion 330 is formed at the center of the inner bottom surface of the lower inner shell 300, and a support shaft 340 is fixedly installed at the center of the protrusion 330 to rotatably support the blade assembly 500. At this time, the protrusion 330 of the lower inner shell 300 is inserted into the protrusion insertion groove 530 formed in the lower center of the blade 510 of the blade assembly 500 to be described later, the upper inner shell through the lower portion of the blade 510. Not only the amount of water introduced into the 400 is reduced, foreign matter contained in the water is also filtered.

The upper inner shell 400 is installed on the open upper portion of the lower inner shell 300 to seal the lower inner shell 300, is formed to open to the upper. At the center of the bottom surface of the upper inner shell 400, a rotating shaft through hole 410 is formed through which the rotating shaft 520 of the blade assembly 500 to be described later is formed, and at the center of the bottom surface of the upper shell 400, the blade assembly 500 is formed. The rotating shaft 520 penetrates and the boss portion 420 connected to the rotating shaft through hole 410 protrudes downward. A plurality of resistance plates 430 protrude radially around the boss 420.

At this time, the boss portion 420 of the upper inner shell 400 is formed to protrude further downward than the resistance plate 430, the boss portion insertion groove formed in the upper center of the blade 510 of the blade assembly 500 to be described later ( 540 is inserted. The boss 420 has an inner diameter substantially equal to the diameter of the rotating shaft through hole 410.

The vane assembly 500 is that the rotation is controlled according to the flow rate of the water in the process of water is introduced into and discharged into the lower inner shell 300, the blade car 510 is rotatably installed in the lower inner shell 300, the blade ( It consists of a rotation shaft 520 integrally coupled to the center of the 510. The rotating shaft 520 penetrates through the boss portion 420 and the rotating shaft through hole 410 of the upper inner shell 400, and the front end thereof is coupled to be interlocked with the counting device 600.

At this time, the lower and upper centers of the blade 510 is formed with a protrusion insertion groove 530 and a boss insertion groove 540 into which the protrusion 330 and the boss 420 are respectively inserted. In the center of the blade car 510 is formed a flowing communication hole 550 penetrated up and down to enable the flow of water, the projection insertion groove 530 and the boss insertion groove 540 by the flow communication hole 550 is formed. Communicate with each other. A support shaft insertion groove 560 into which the support shaft 340 is inserted is formed at the center of the protrusion insertion groove 530 formed at the bottom of the blade 510.

Hereinafter will be described in detail the operation of the water meter according to an embodiment of the present invention configured as described above.

As shown in FIG. 4, water passing through the inlet 110 of the lower outer shell 100 connected to the water supply line is introduced into the lower outer shell 100 through the strainer 130. Foreign matter contained in the water flowing in this process is filtered by the strainer 130.

Water introduced into the lower outer shell 100 is introduced into the lower inner shell 300 through the inlet hole 310 of the lower inner shell 300 and then discharged through the discharge hole 320 of the lower inner shell 300. As described above, the blade 510 of the blade assembly 500 is rotated by the flow of water in the lower inner shell 300. Water discharged through the discharge hole 320 of the lower inner shell 300 is discharged to the outside through the discharge port 120 of the lower outer shell (100).

When the vane 510 of the vane assembly 500 rotates, the gear 610 and the counting unit 620 of the counting device 600 linked thereto operate. Since the blade assembly 500 rotates in proportion to the flow rate of water passing through the lower inner shell 300, the amount of water flowing through the inlet 110 of the lower outer shell 100 is measured through the counting unit 620.

On the other hand, the boss portion 420 protruding in the center of the bottom surface of the upper inner shell 400 is inserted into the boss portion insertion groove 540 formed on the blade 510 of the blade assembly 500, the upper inner shell 400 and the blade car The contact area of the assembly 500 is increased. That is, the contact area between the rotation shaft 520 of the blade assembly 520 and the upper inner shell 400 increases primarily by the length of the boss 420, and the blade 510 by the length of the boss 420. And the contact area of the upper inner shell 400 is increased. Therefore, not only the amount of water introduced into the upper inner bag 400 is reduced, but also the inflow of foreign substances contained in the water is blocked.

The protrusion 330 protruding in the center of the inner bottom surface of the lower inner shell 300 is inserted into the protrusion inserting groove 530 formed in the lower portion of the vane 510 of the vane assembly 500, whereby the lower inner shell 300 and the vane assembly ( The contact area of 500 is increased. That is, the contact area between the lower inner shell 300 and the blade 510 increases as much as the length of the protrusion 330. Therefore, the amount of water flowing into the upper inner bag 400 through the lower portion of the blade 510 is reduced, as well as the inflow of foreign matter contained in the water is blocked.

As described above, the present invention has been described based on the preferred embodiment, but the present invention is not limited to the specific embodiments, and those skilled in the art within the scope described within the utility model registration claims You can change it.

1 is a perspective view of the lower inner shell, the upper inner shell and the blade assembly of the wet water meter according to the prior art separated.

Figure 2 is a cross-sectional view of the lower inner shell, upper inner shell and the blade assembly of Figure 1 separated.

3 is a cross-sectional view showing a state in which the lower inner shell, upper inner shell and the blade assembly of Figure 1 is coupled.

4 is a cross-sectional view showing a water meter according to an embodiment of the present invention.

5 is a perspective view of the lower inner shell, upper inner shell and the blade assembly of Figure 4 separated.

Figure 6 is a cross-sectional view of the lower inner shell, upper inner shell and the blade assembly of Figure 4 separated.

Figure 7 is a cross-sectional view of the lower inner shell, upper inner shell and the blade assembly of Figure 4 coupled.

<Explanation of symbols for the main parts of the drawings>

100: lower outer shell 110: inlet

120 outlet 130 strainer

200: upper outer shell 210: cap

300: lower inner bag 310: inlet hole

320: discharge hole 330: protrusion

340: support shaft 400: upper inner shell

410: rotating shaft through hole 420: boss

430: resistance plate 500: vane assembly

510: wing 520: axis of rotation

530: protrusion insertion groove 540: boss insertion groove

550: water flow hole 560: support shaft insertion groove

600: counting device 610: gear

620: counting unit 630: transparent plate

Claims (3)

A lower inner shell opened to an upper portion, an upper upper inner shell formed at an open upper portion of the lower inner shell and having a rotating shaft through-hole formed at a center of the bottom surface, and having a plurality of resistance plates radially protruding from the lower surface, and rotatably installed at the lower inner shell In the water meter including a vane assembly coupled to the center of the vane and the vanes and composed of a rotating shaft passing through the rotating shaft through hole, In the center of the bottom surface of the upper inner shell is connected to the rotary shaft through-hole is formed through the rotary shaft penetrating and protruding downward than the resistance plate, the upper central portion of the blade car is formed with a boss portion insertion groove into which the boss portion is inserted Water meter featured. The method of claim 1, Protruding portion protrudes from the bottom in the center of the inner bottom of the lower inner shell, the water meter, characterized in that the lower portion of the blade car is formed with a projection insertion groove into which the projection is inserted. The method of claim 2, Water flow meter is formed in the center of the blade car so that the flow of water flow is possible, characterized in that the boss portion insertion groove and the projection insertion groove is connected through the flow hole.

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