KR200384155Y1 - Water meter - Google Patents

Abstract

 The present invention relates to a water meter having a simplified structure by reducing the number of components, the water meter body 130 having an inlet (130a) and an outlet (130b), and the flow of water in the water meter body (130) A lower inner shell 150 having an inlet hole 150a and an outlet hole 150b through which the inflowed water passes and an upper inner shell 140 installed to cover an upper portion of the lower inner shell 150, and a lower portion A vane assembly 160 rotatably installed in the inner shell 150 and a counting device 170 operated by rotation of the vane assembly 160 are included. And, in the center of the lower inner shell 150 is provided with a support shaft 155 for rotatably supporting the blade assembly 160, the blade assembly 160 is rotated by water passing through the lower inner shell 150 It is rotatably supported by the blade 161, the insertion groove 162b, which is coupled to the center of the blade 161 and the end of the support shaft 155 is inserted, and the boss 176 provided in the counting device 170. The axle 162a includes an integrated vane shaft 162 that is integrated.

Description

Water meter {Water meter}

The present invention relates to a water meter, and more particularly, to a water meter that is simply improved in structure by reducing the number of components.

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

Conventional water meter, as shown in Figure 1, includes the upper and lower outer shell 10, 20, upper and lower inner shell 30, 40, vane assembly 50 and the counting device 60. .

The lower outer shell 20 has an inlet 20a and an outlet 20b and is connected to a water supply line. The inlet 20a is provided with a strainer 21 for preventing foreign matter from flowing into the water meter.

The upper outer shell 10 is installed to be closed with the lower outer shell 20 on the upper portion of the lower outer shell 20. The upper portion of the upper outer shell 10 is opened, and the open portion is opened and closed by a cap 11 pivotally coupled to the upper outer shell 10.

The lower inner shell 40 is installed between the inlet 20a and the outlet 20b inside the lower outer shell 20. A plurality of inflow holes 40a are formed in the lower outer periphery of the lower inner shell 40, and a plurality of outflow holes 40b are formed in the upper outer periphery of the lower inner shell 40. As shown in FIG. 2, a support shaft 43 for rotatably supporting the blade assembly 50 is provided at the center of the lower inner shell 40. The support shaft 43 is made of stainless steel, the upper end is provided with a support projection 45 of cemented carbide material having a large wear resistance.

The upper inner shell 30 is installed on the lower outer shell 20 to seal the open upper portion of the lower inner shell 40. An insertion hole 30a is formed in an approximately center portion of the upper inner shell 30, and a plurality of guide plates 31 are installed at the lower portion of the upper inner shell 30 to protrude.

The vane assembly 50 includes a vane 51 and a vane shaft 52 coupled to the vane 51. The blade 51 is rotatably installed in the lower inner shell 40, and the blade shaft 52 protrudes into the upper inner shell 30 through the insertion hole 30a of the upper inner shell 30. As shown in Figure 2, the blade shaft 52 is made of a synthetic resin material, the upper end of the stainless steel metal shaft 53 is inserted and coupled, the lower end is inserted into the insert 54 of the sapphire material . One side of the upper end of the blade shaft 52 is provided with a gear portion 52a.

The counting device 60 includes a plurality of gears 61, 62, a counting unit 63, and a transparent plate 64. One gear 61 of the plurality of gears 61 and 62 is gear-connected with the gear portion 52a of the rotation shaft 52. The counting unit 63 is operated by a plurality of gears 51, 52 that cooperate with the vane assembly 50.

However, among the components constituting the water meter as described above, the lower inner shell 40 and the vane assembly 50 have a large number of components and are complicated to manufacture, thereby increasing the manufacturing cost of the entire water meter.

That is, as shown in FIG. 2, the support shaft 43 installed on the lower inner shell 40 to support the blade assembly 50 is made of stainless steel, and the blade assembly is formed on the upper end of the support shaft 43. Since the support protrusion 45 provided to contact the insert 54 of 50 is made of cemented carbide, the material cost is high and the manufacturing is complicated.

In addition, the vehicle body assembly 50 is also made of the metal shaft 53 and the sapphire insert 54 of different materials are respectively coupled to the upper and lower ends of the blade shaft 52 of the synthetic resin material coupled to the blade car 51, material costs Carrying a lot is complicated to manufacture.

In addition, the conventional water meter as described above, the support protrusions 45 protruding at the end of the support shaft 43 to support the blade assembly 50 is made of cemented carbide material, the blade assembly 50 is supported thereon Since the insert 54 is made of sapphire material, noise caused by friction is greatly generated when the blade wheel 51 rotates at a high speed.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a water meter capable of reducing material costs and manufacturing costs and reducing operating noise by improving the vane assembly and the lower inner shell to a simple structure.

Water meter according to the present invention for achieving the above object, the water meter body having an inlet and an outlet, a lower inner shell provided on the flow path of the water inside the water meter body, and an upper portion installed to cover the upper portion of the lower inner shell An inner shell, a vane assembly rotatably installed inside the lower inner shell, and a counting device operated by the rotation of the vane assembly.

In this configuration, the center of the lower inner shell is provided with a support shaft for rotatably supporting the blade assembly, the blade assembly is a blade of the rotor rotated by water passing through the lower inner shell and the center of the blade; It consists of an integral blade axle.

The integrated rotor shaft includes an insertion groove into which an end of the support shaft is inserted and an axle rotatably supported by a boss provided in the counting device.

In the present invention, the upper end of the support shaft is provided with an arcuate support projection of a round surface, the insertion groove is preferably a rounded arcuate shape to correspond to the support projection.

In addition, the upper end of the shaft projection of the blade shaft is preferably a rounded arcuate surface.

In addition, both the axle shaft and the support shaft is preferably made of a synthetic resin mold.

Hereinafter, with reference to the accompanying drawings will be described for the upper inner case and the water meter having a water meter according to a preferred embodiment of the present invention.

Figure 3 is a side cross-sectional view schematically showing the configuration of the water meter according to a preferred embodiment of the present invention, Figure 4 is an exploded cross-sectional view showing the main components of the water meter shown in FIG.

As shown in Figure 3, the water meter according to a preferred embodiment of the present invention, the water meter body 110, upper and lower inner shell 140, 150, vane assembly 160 and the counting device 170 It includes.

Water meter body 110 is composed of an upper outer shell 120 and a lower outer shell 130.

The lower outer shell 130 has an inlet 130a and an outlet 130b, and is connected to the water supply line so that a flow path of water is formed between the inlet 130a and the outlet 130b. A strainer 131 is installed at the inlet 130a. The strainer filters out foreign substances contained in the water flowing through the inlet 130a to prevent foreign substances from flowing into the water meter body 110. Inside the lower outer shell 130 is provided with a connection hole (130c) approximately perpendicular to the virtual connecting line connecting the inlet (130a) and the outlet (130b), the lower inner shell 150 is placed in this connection hole (130c) do.

The upper outer shell 120 is coupled to the lower outer shell 130 and sealed to the upper portion of the lower outer shell 130. The upper portion of the upper outer shell 120 is open, the cap 121 is pivotally coupled to one side of the upper outer shell 120. The cap 121 opens and closes the open upper portion of the upper outer shell 120.

The lower inner shell 150 is installed inside the lower outer shell 130 to cover the connection hole 130c of the lower outer shell 130. A plurality of inflow holes 150a are formed at the outer periphery of the lower inner shell 150, and a plurality of outflow holes 150b are formed at the upper outer periphery of the lower inner shell 150. Water introduced through the inlet 130a of the lower outer shell 130 is guided to the inlet hole 150a of the lower inner shell 150 and introduced into the lower inner shell 150. The water introduced into the lower inner shell 150 is discharged through the outlet hole 150b while driving the vane assembly 160.

As shown in FIG. 4, a support shaft 155 for supporting the vane assembly 160 is installed at the center of the lower inner shell 150. The support shaft 155 is made of a synthetic resin material, the upper end portion is provided with an arcuate support protrusion 155a of a round surface. The arcuate support protrusion 155a is formed by integrally rounding the upper end of the support shaft 155 made of synthetic resin.

As shown in FIG. 1, the upper inner shell 140 is coupled to the upper portion of the lower outer shell 130 so that its lower surface seals the open upper portion of the lower inner shell 150. Insertion holes 140a are provided at the center of the upper inner shell 140, and a plurality of guide plates 141 are disposed around the insertion holes 140a at approximately equal intervals.

The vane assembly 160 is composed of a vane 161 and an integral vane shaft 162 coupled to a center of the vane 161. The blade 161 is rotatably installed in the lower inner shell 150, and the integrated blade shaft 162 protrudes upward through the insertion hole 140a of the upper inner shell 140. The integrated rotor shaft 162 is made of a synthetic resin material, as shown in Figure 4, the upper end is provided with a shaft projection (162a), the lower end is formed with an insertion groove 162b is inserted into the support shaft 155. do. The shaft protrusion 162a is rounded to form an end of the arch, and the insertion groove 162b is also rounded to form a surface of the arch. One side of the integrated blade shaft 162 is provided with a gear portion (162c). In the integrated rotor shaft 162, the shaft protrusion 162a, the insertion groove 162b and the gear portion 162c are integrally formed through one molding process.

The counting device 170 is installed above the upper inner shell 140 inside the upper outer shell 120, and includes a gear assembly 171, a counting unit 174, and a transparent plate 175. The gear assembly 171 includes a plurality of gears 172 and 173, and the gear part 162c of the rotation shaft 162 is connected to any one gear 172 among the plurality of gears 172 and 173. do. The counting unit 174 is connected to and interlocked with the gear assembly 171. When the blade assembly 160 is rotated by the water flowing in the lower inner shell 150, the counting unit 174 is operated in conjunction with this. The transparent plate 175 is installed to cover the counting unit 174 and to be exposed to the open upper portion of the upper outer shell 120. A boss 176 for rotatably supporting the vane assembly 160 is provided at the center of the counting device 170, and the boss 162a of the vane assembly 160 is inserted therein.

Operation of the water meter according to a preferred embodiment of the present invention made of such a configuration is as follows.

As shown in FIG. 3, the water passing through the inlet 130a of the lower outer shell 130 connected to the water supply line is introduced into the lower outer shell 130 through the strainer 131. Water filtered by the strainer 131 is introduced into the lower inner shell 150 through the inlet hole 150a of the lower inner shell 150. The water introduced into the lower inner shell 150 rotates the blade wheel 161 of the blade assembly 160 while forming a vortex in the lower inner shell 150. When the vane assembly 160 is rotated, the gear assembly 171 and the counting unit 174 of the counting device 170 are operated in conjunction with the vane assembly 160. Since the blade assembly 160 rotates in proportion to the flow rate of the water passing through the lower inner shell 150, the amount of water introduced through the inlet 130a of the lower outer shell 130 is measured through the counting unit 174.

The water that rotates the blade car 161 inside the lower inner shell 150 exits through the outlet hole 150b of the lower inner shell 150, and then is discharged to the outlet 130b of the lower outer shell 130.

In the present invention as described above, because the support shaft 155 for supporting the blade assembly 160 and the integral blade shaft 162 that is rotated and supported in contact with the support shaft 155 is made of a synthetic resin material, the blade assembly ( The operation of 160 does not generate much noise.

According to the present invention as described above, in order to rotatably support the blade assembly, the support shaft installed on the lower inner shell is made of a synthetic resin mold, the blade shaft coupled to the center of the blade wheel is a shaft projection, gear portion and the insertion groove Since it is an integral synthetic resin mold made through this one molding process, the number of components of the whole water meter is smaller, the structure is simpler, and the manufacturing is easier than in the prior art. Therefore, there is an effect of reducing the manufacturing cost by reducing the material cost and manufacturing time.

In addition, according to the present invention, since both the support shaft for supporting the blade assembly and the rotating blade assembly in contact with the support shaft are made of a synthetic resin material, noise is not greatly generated during operation of the blade assembly.

As described above, the present invention has been described by taking specific embodiments as an example, but the present invention is not limited to the configuration and operation as shown and described. That is, the present invention is capable of various modifications and changes within the spirit and scope of the utility model registration claims described. Accordingly, all such suitable modifications and changes and equivalents should be considered to be within the scope of the present invention.

1 is a side cross-sectional view schematically showing a conventional water meter.

FIG. 2 is an exploded cross-sectional view showing the main components of the conventional water meter shown in FIG.

Figure 3 is a side cross-sectional view schematically showing a water meter according to a preferred embodiment of the present invention.

Figure 4 is a side cross-sectional view showing the main components of the water meter shown in FIG.

<Description of Symbols for Major Parts of Drawings>

110; water meter body 120, 130; upper and lower outer shell

140,150; upper and lower inner 155; support shaft

160; vane assembly 161; vane

162; integral blade axle 170;

Claims (4)

A water meter body having an inlet and an outlet, a lower inner shell provided on the flow path of water inside the water meter body and having an inlet and an outlet hole through which the inflowed water passes, and an upper portion installed to cover the upper portion of the lower inner shell A water meter comprising an inner shell, a vane assembly rotatably installed inside the lower inner shell, and a counting device operated by rotation of the vane assembly, A support shaft for rotatably supporting the blade assembly is provided at the center of the lower inner shell, wherein the blade assembly is coupled to a central portion of the blade and the blades rotated by water passing through the lower inner shell of the support shaft. Water meter, characterized in that it comprises an insertion groove in which the end is inserted and an integral rotor shaft which is integrally supported by a shaft projection rotatably supported by the boss provided in the counting device. The method of claim 1, The upper end of the support shaft is provided with an arcuate support projection of a round surface, the insertion groove of the blade axle is characterized in that the arc shaped to correspond to the support projection. The method according to claim 1 or 2, A water meter, characterized in that the upper end of the shaft projection of the blade axle has a rounded arcuate surface  The method of claim 1, The wing shaft and the support shaft are both water meter, characterized in that made of a synthetic resin molding.