KR102101615B1 - Circulating water meter and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a water meter and, more specifically, to a circulating water meter which circulates a fluid flowing into a counting unit case to prevent proliferation of microorganisms in the counting unit case, and sets antifreeze injected into the counting unit case within a prescribed temperature range to proactively eliminate a volume expansion cause of antifreeze by a temperature increase of outside air, and a manufacturing method thereof. The present invention provides the following effects. According to the present invention, microorganisms are prevented from proliferating in a counting unit case to improve a sanitation level of fluid, and volume expansion of antifreeze is prevented to prevent malfunction leading to leakage of antifreeze or deformation of a counting unit of a water meter to reduce a malfunction rate of the water meter. Also, a starting flow, namely a minimal flow for rotating a propeller is improved by a link effect in a process of circulating a fluid flowing into a lower and an upper counting unit case in which the flowing fluid comes in contact with the propeller. When removing air flowing into a water meter to examine an error of the water meter, air flowing into the counting unit case is effectively removed to allow targeted air removal and accurate examination.

Description

Circulating water meter and manufacturing method thereof

The present invention relates to a water meter, and more specifically, by preventing the growth of microorganisms inside the counting case by allowing the fluid flowing into the counting case to circulate, and the antifreeze injected into the counting part to a predetermined temperature range It relates to a circulating water meter that preemptively solves the factor of volume expansion of the antifreeze due to an increase in the outside temperature by setting it to inside, and a method for manufacturing the same.

Water that is mainly used so far is supplied to each household or place of use of water, and then, after a water business operator takes water from a water source and goes through a water treatment process, it is supplied to a place where each house or water is used, that is, a place where water is finally used. Most of the water is supplied through piping.

In this process, expenses are set and charged according to the amount of water used by each household, individual, or branch to cover the cost required to continuously supply clean water.

Therefore, accurately measuring the amount of water used by the user is a problem to be solved prior to billing, and for this purpose, by installing a water meter (water meter) at the final use of water such as each household, water is collected from the water source and supplied at the end of the process. The water meter is installed in a pipeline immediately before using to measure the amount of water used.

To this end, a water wheel is installed in the water meter to measure the amount of water used by rotation, and when the water flows, the wheel is rotated, and the rotated wing car eventually raises the numerical value of the water meter to present the water consumption as a metered value. In general, by comparing the numerical value of the water meter presented in the delivery with the numerical value presented in the water meter of the month, the amount of water is measured and billed to receive the cost.

The conventional water meter has a problem in that the fluid introduced into the counting case is stagnant, thereby creating an environment in which microorganisms can be generated, and in particular, the hygiene of the fluid is inhibited due to sediment on the pipeline introduced by an external factor. . In addition, there is a problem in that the antifreeze is leaked due to the expansion of the volume of the antifreeze injected into the flow display or the flow display is broken.

In order to overcome the above problems, the present applicant prevents microorganisms from growing inside the counting case by allowing the fluid introduced into the counting case to circulate, and the antifreeze injected inside the counting part is within a predetermined temperature range. By setting, the circulating water meter that preemptively solved the factor of volume expansion of the antifreeze according to the temperature rise of the outside air and its manufacturing method were researched and developed.

Utility Model Registration No. 20-0455340 (2011.08.25.)

An object of the present invention is to provide a circulating water meter and a method of manufacturing the same, which can prevent microorganisms from growing inside the counting unit case and prevent volume expansion of the antifreeze due to an increase in ambient temperature.

In order to achieve the above object, the present invention includes a main body portion 100 and a casing portion 200 in which the main body portion 100 is accommodated, and the main body portion 100 includes a main body portion 100. The rotor blade case 110 disposed on the lower side, the rotor blade 120 accommodated in the rotor blade case 110, the counting portion case 130 disposed on the upper side of the main body 100, and the counting portion case 130 It includes a counting unit 140 to be accommodated, the rotor blade case 110 is formed on the lower circumferential surface of the rotor blade support shaft 111 and the rotor blade formed in the vertical direction of the center portion of the rotor blade case 110, 110 The fluid inlet hole 112 through which fluid flows from the fluid inlet pipe 220 into the interior of the rotor blade case 110 is formed on the upper circumferential surface of the rotor blade case 110, and then flows into the rotor blade case 110. The fluid comprises a fluid discharge hole 113 through which the fluid flow path 211 is discharged, and the rotor blade 120 has a number in the center of the rotor blade 120. It is formed in the direction, and is supported rotatably on the rotor support shaft 111, and includes a rotor rotation shaft 121 formed with a drive gear 121a on the upper portion, and the counting unit case 130 is included in the counting unit case 130. It is formed in the central portion of the rotor blade shaft 121 through which the rotor blade shaft 121 passes through 131, and is formed on the lower circumferential surface of the counting unit case 130, the fluid flowing into the counting unit case 130 is fluid flow It includes a fluid discharge hole 132 discharged to the furnace 211, the counting unit 140 is formed on the lower side of the counting unit 140, the gear gear meshing (齒 合) engaged with the drive gear (121a) (141), is formed on the upper side of the counting unit 140, interlocked with the meter gear 141, and includes a flow rate display unit 142 for integrating the flow rate of the fluid, the flow rate display unit 142 is an internal The antifreeze (A) is injected into the empty space (S), and the temperature range of the injected antifreeze (A) is set at 38 ° C to 42 ° C. The body portion 100 is inserted into the casing portion 200, and the body portion inserting portion 210 and the body portion inserting portion 210 having a fluid flow path 211 through which fluid flows are formed. Is connected to one side, the fluid inlet pipe 220 of the fluid is introduced into the fluid inlet hole 112 of the wing case 110, and the other side of the body portion insertion portion 210, but the fluid flow path 211 A circulating water meter and a rotor wheel case 110 disposed under the body portion 100, and a rotor wheel accommodated in the rotor wheel case 110, comprising a fluid discharge pipe 230 through which fluid flowing through is discharged. Preparing a body part 100 including 120, a counting part case 130 disposed on an upper side of the body part 100, and a counting part 140 accommodated in the counting part case 130 ( S100); A fluid flow path 211 in which a fluid flows inside the casing part 200 is communicated with one side of the body part inserting part 210 and the body part inserting part 210, but fluid flows into the rotor case 110. A fluid inlet pipe 220 through which fluid flows into the ball 112 and a fluid outlet pipe 230 communicating with the other side of the body portion inserting portion 210 and through which the fluid flowing through the fluid flow path 211 is discharged Preparing a casing portion 200 comprising (S200); Including (S300); inserting the body portion 100 in the casing 200, the step S100, the rotor support shaft 111 formed in the vertical direction of the center portion of the rotor blade case 110, and the rotor blade case It is formed on the lower circumferential surface of the (110), the fluid inlet hole 112 through which the fluid (W1) flows from the fluid inlet pipe 220, and is formed on the upper circumferential surface of the rotor blade case 110, (110) preparing a rotorcraft case 110 including a fluid discharge hole 113 through which the fluid W2 flowing into the interior is formed (S110), and is formed in a vertical direction in the center of the rotorcraft 120, A step (S120) of preparing a rotor blade 120 including a rotor blade rotation shaft 121 which is rotatably supported by the rotor blade support shaft 111 and having a driving gear 121a formed on an upper portion of the rotor blade 120 (S120), and a counting unit It is formed in the central portion of the case 130, the rotor blade shaft through-hole 121 passes through the rotor shaft 131, and the lower circumferential surface of the counter case 130 The step of preparing the counting unit case 130 including the fluid discharge hole 132 formed on the, and the fluid W4 flowing into the counting unit case 130 is discharged to the fluid flow path 211 (S130). And, is formed on the lower side of the counting unit 140, the gear gear 141 meshing (齒 合) engaged with the drive gear (121a), is formed on the upper side of the counting unit 140, the meter gear (141) And a step (S140) of preparing a counting unit 140 including a flow rate display unit 142 for integrating the flow rate of the fluid through the flow, and the step of S140 is an empty space (S) inside the flow rate display unit 142. ), But the temperature range of the injected antifreeze (A) is set between 38 ° C and 42 ° C.

The present invention exerts the following effects.

According to the present invention, microorganisms are prevented from growing inside the counting unit case, the hygiene level of the fluid is improved, and the volume expansion of the antifreeze is prevented to prevent the leakage of antifreeze or the failure leading to deformation of the water meter counting unit. It has the advantage of reducing the failure rate. In addition, the starting flow rate, that is, the effect of improving the minimum flow rate that enables the rotor to rotate, is an interlocking effect made in the process of circulating the fluid flowing into the lower side and upper side counting case where the fluid flow is tangent to the rotor. In order to test the error of the water meter, when the air introduced into the water meter is removed, the air introduced into the case of the counting unit is effectively removed, so that the desired air removal and accurate calibration can be achieved.

1 is an exploded perspective view of a circulating water meter according to the present invention.
2 is a cross-sectional view of a circulating water meter according to the present invention.
3 is a view showing a flow of fluid in a conventional water meter.
4 is a view showing the flow of fluid in a circulating water meter according to the present invention.
5 to 6 are block diagrams of a method for manufacturing a circulating water meter.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the scope of rights of the present invention should be grasped by describing the claims. Also, descriptions of well-known technologies that obscure the subject matter of the present invention will be omitted.

However, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to that shown in the drawings, and the thickness is enlarged to clearly express various parts and regions. Did.

In addition, in the description of the present invention, direction limitations such as “up” and “down” are only indicated based on the form of FIG. 1 for ease of understanding, and it is revealed that the direction will be differently indicated if the reference line (or drawing) is different. Put it.

The present invention relates to a water meter, and more specifically, by preventing the growth of microorganisms inside the counting case by allowing the fluid flowing into the counting case to circulate, and the antifreeze injected into the counting part to a predetermined temperature range It relates to a circulating water meter that preemptively solves the factor of volume expansion of the antifreeze due to an increase in the outside temperature by setting it to inside, and a method for manufacturing the same.

Figure 1 is an exploded perspective view of a circulating water meter according to the present invention, Figure 2 is a cross-sectional view of a circulating water meter according to the present invention, Figure 3 is a view showing the flow of fluid in a conventional water meter, Figure 4 is It is a view showing the flow of a fluid in a circulating water meter according to the present invention, and FIGS. 5 to 6 are block diagrams of a method for manufacturing a circulating water meter.

As shown in Figure 1, the circulation type water meter according to the present invention is coupled to the body portion 100, the casing portion 200 in which the body portion 100 is accommodated, and the upper side of the casing portion 200. It is configured to include a protective part 300.

The main body portion 100 includes a rotor blade case 110 disposed under the main body portion 100, a rotor blade 120 accommodated in the rotor blade case 110, and a counting portion case disposed above the main body portion 100. It comprises a 130, and the counting unit 140 accommodated in the counting unit case 130.

The following is a description of the tea case 110. The rotor blade case 110 is a portion in which the rotor blade 120 is accommodated, and the fluid wheel is formed on the lower circumferential surface of the rotor blade case 110 and the rotor blade support shaft 111 formed vertically in the central portion of the rotor blade case 110. It comprises a ball 112, and a fluid discharge hole 113 formed on the upper circumferential surface of the wing case 110.

The fluid inlet hole 112 is a portion where the fluid W1 (FIG. 4) flows from the fluid inlet pipe 220 into the inside of the rotor blade case 110, and the fluid discharge hole 113 is moved into the interior of the rotor blade case 110. This is the portion where the fluid W2 (FIG. 4) is discharged to the fluid flow path 211.

The wing car 120 will be described. The rotor blade 120 is a portion that is rotated according to the flow of the fluid, and the rotor blade shaft 121 is formed in a vertical direction in the central portion of the rotor blade 120. The rotor blade rotation shaft 121 is rotatably supported on the rotor blade support shaft 111, and a driving gear 121a is formed on the upper rotor blade shaft 121.

The rotational force of the rotor 120 generated according to the flow of the fluid is transmitted to the instrument gear 141, which will be described later, engaged with the driving gear 121a.

The counting case 130 will be described. The counting unit case 130 is a portion in which the counting unit 140 is accommodated, and is formed on the lower circumferential surface of the counting unit case 130 and the rotor rotation shaft through hole 131 formed in the center of the counting unit case 130. It is configured to include a fluid discharge hole 132.

The rotor blade shaft through-hole 131 is a portion through which the rotor blade shaft 121 passes, and the fluid discharge hole 132 is the fluid (W3, FIG. 4) introduced into the counting case 130 into the fluid flow path 211. This is the discharged part.

2 is a cross-sectional view of a circulating water meter according to the present invention. 2, since the diameter (D131) of the rotor blade shaft through hole 131 is larger than the diameter (D121) of the rotor blade shaft 121, the fluid flowing into the rotor blade case 110 is a fluid discharge hole 113 In addition to being discharged to the fluid flow path 211 (W2, FIG. 4), it is introduced into the counting unit case 130 through the space between the rotor blade shaft through hole 131 and the rotor blade shaft 121 (W3) , Fig. 4).

3 is a view showing a flow of fluid in a conventional water meter. Referring to FIG. 3, in the conventional water meter, since a fluid discharge hole was not formed in the counting case, the fluid introduced into the counting case becomes stagnant, thereby creating an environment in which microorganisms are well-produced, and hygiene of the fluid is impaired. There was a problem.

4 is a view showing the flow of fluid in a circulating water meter according to the present invention. As the circulating water meter according to the present invention improves this problem, as shown in FIG. 4, the fluid discharge hole 132 is formed in the counting unit case 130 to flow into the counting unit case 130. By allowing the fluid to be discharged to the fluid flow path 211 (see W4), an environment in which microorganisms are well generated is prevented.

In addition, the circulating water meter according to the present invention has an improved starting flow rate, that is, a minimum flow rate to allow the rotor to rotate, and accordingly has a merit that more accurate flow measurement is possible.

The counting unit 140 will be described. The counting unit 140 is a part that receives the rotational force from the rotor blade 120 and accumulates the flow rate of the fluid, and the meter gear 141 and the counting unit 140 are formed below the counting unit 140. It comprises a flow rate display unit 142 formed on the upper side.

The meter gear 141 is engaged with the driving gear 121a, and is a part that receives the rotational force of the rotor 120, and the flow rate indicator 142 is interlocked with the meter gear 141 to pass fluid. This is the part for integrating the flow rate.

On the other hand, as shown in Figures 2 and 4, the antifreeze liquid (A) is injected into the empty space (S) inside the flow rate display unit 142, which is formed by mixing glycerin and distilled water, etc. It serves to improve the sensitivity of the display unit 142 so that more accurate weighing can be achieved.

The antifreeze (A) has a property that the volume expands when the outside air temperature rises. In the related art, there has been a problem in that the flow rate display unit malfunctions due to the volume expansion of the antifreeze (A).

To improve this problem, in the circulating water meter according to the present invention, the antifreeze solution A injected into the empty space S inside the flow rate display unit 142 may be set within a predetermined temperature range. Here, the predetermined temperature range is a temperature range of the antifreeze liquid (A) that can reach its maximum due to an increase in the outside temperature, and is preferably set between 38 ° C and 42 ° C, but is not necessarily restricted thereto, and its value can be adjusted. Of course it can.

Since the antifreeze (A) injected into the empty space (S) inside the flow rate display unit (142) is set to a predetermined temperature range, it is in the maximum expanded state, so the volume expansion of the antifreeze (A) in response to an increase in the outside temperature is unforeseen. It has the advantage of being prevented.

5 to 6 are block diagrams of a method for manufacturing a circulating water meter. Hereinafter, a method of manufacturing a circulating water meter according to the present invention will be described with reference to FIGS. 5 to 6.

The manufacturing method of the circulating water meter according to the present invention, as shown in Figure 5, the step of preparing the main body 100 (S100), and the step of preparing the casing 200 (S200), and the casing unit It includes a step (S300) of inserting the body portion 100 in the (200).

The main body 100 in step S100 includes the wing case 110 disposed at the lower side, the wing vehicle 120 accommodated in the wing vehicle case 110, the counting unit case 130 disposed at the upper side, and the counting unit case It comprises a counting unit 140 accommodated in 130.

And, step S100, as shown in Figure 6, the step of preparing the wing case 110 (S110), the step of preparing the wing vehicle 120 (S120), and the step of preparing the counting unit case 130 (S130) and preparing the counting unit 140 (S140).

In the step S110, the wing case 110 is formed on the lower circumferential surface of the wing support shaft 111 formed in the vertical direction in the central portion, and the fluid W1, FIG. 4 flows inward from the fluid inlet pipe 220. The fluid inlet hole 112 is formed on the upper circumferential surface, and is configured to include a fluid discharge hole 113 through which the fluid W2 (FIG. 4) introduced into the rotor case 110 is discharged.

The rotor blade 120 in step S120 is formed in the vertical direction in the central portion, is rotatably supported on the rotor blade support shaft 111, and is configured to include the rotor blade shaft 121 on which the drive gear 121a is formed.

The counting unit case 130 in step S130 is formed in the central portion, the rotor blade shaft through-hole 121 is penetrated through the rotor shaft 131, and is formed on the lower circumferential surface, the fluid flowing into the counting unit case 130 (W4, Figure 4) is configured to include a fluid discharge hole 132 discharged to the fluid flow path 211.

The counting unit 140 in step S140 is formed on the lower side, the meter gear 141 meshed with the driving gear 121a, and formed on the upper side, the fluid being interlocked with the meter gear 141 It comprises a flow rate display unit 142 for integrating the flow rate of the.

In step S140, the antifreeze liquid A is injected into the empty space S inside the flow rate display unit 142, but the temperature range of the injected antifreeze liquid A may be set between predetermined temperature ranges. Here, the predetermined temperature range is a temperature range of the antifreeze liquid (A) that can reach its maximum due to an increase in the outside temperature, and is preferably set between 38 ° C and 42 ° C, but is not necessarily restricted thereto, and its value can be adjusted. Of course it can.

In step S200, the casing unit 200 is in communication with one side of the body portion inserting portion 210, the body portion inserting portion 210 is formed with a fluid flow path 211 through which the fluid flows, the rotor case 110 The fluid inlet pipe 220 through which the fluid flows into the fluid inlet hole 112, and the other side of the body portion insertion portion 210, but the fluid discharge pipe (2) through which the fluid flowing through the fluid flow path 211 is discharged ( 230).

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the present invention without departing from the technical spirit of the present invention. It will be clear to those who have knowledge.

100: main body
110: next car case
111: Axial support shaft
112: fluid inlet hole
113: fluid discharge hole
120: ripe tea
121: rotor blade axis
121a: Drive gear
130: counting case
131: Ikcha rotating shaft through hole
132: fluid discharge hole
140: counting unit
141: Instrument gear
142: flow rate indicator
200: casing part
210: main body insert
211: fluid flow path
212: step
220: fluid inlet pipe
230: fluid discharge pipe
300: protection unit
A: Antifreeze
S: empty space inside the flow rate display
W1, W2, W3, W4: Fluid
D121: diameter of the rotor shaft
D131: Diameter of the rotor shaft through-hole

Claims (4)

delete Body portion 100,
The main body portion 100 includes a casing portion 200 is accommodated,

The main body 100 has
The vehicle body case 110 is disposed under the body portion 100,
The wing car 120 accommodated in the wing car case 110,
The counting unit case 130 disposed on the upper side of the main body 100,
It includes a counting unit 140 accommodated in the counting unit case 130,

The wing case 110 is
The rotor blade support shaft 111 formed in the vertical direction of the center portion of the rotor blade case 110,
It is formed on the lower circumferential surface of the rotor blade case 110, the fluid inlet hole 112 and the fluid (W1) flows into the interior of the rotor blade case 110 from the fluid inlet tube 220,
It is formed on the upper circumferential surface of the rotor blade case 110, and includes a fluid discharge hole 113 through which the fluid W2 flowing into the rotor blade case 110 is discharged to the fluid flow path 211,

The wing car 120 is
It is formed in the vertical direction of the center portion of the rotor blade 120, is supported rotatably on the rotor blade support shaft 111, and includes a rotor blade shaft 121 formed with a drive gear 121a on the top,

The counting unit case 130 is
It is formed in the center of the counting unit case 130, the rotor blade shaft through-hole 131 through which the rotor blade shaft 121 passes, and
It is formed on the lower circumferential surface of the counting unit case 130, and includes a fluid discharge hole 132 through which the fluid W4 flowing into the counting unit case 130 is discharged to the fluid flow path 211,

The counting unit 140 includes
The instrument gear 141 is formed on the lower side of the counting unit 140 and meshes with the driving gear 121a.
It is formed on the upper side of the counting unit 140, interlocked with the instrument gear 141 includes a flow rate display unit 142 for integrating the flow rate of the fluid,

The flow rate display unit 142
Antifreeze (A) is injected into the empty space (S) inside, characterized in that the temperature range of the injected antifreeze (A) is set between 38 ℃ to 42 ℃,

The casing part 200 is
The body portion 100 is inserted, the body portion insertion portion 210 is formed with a fluid flow path 211 through which fluid flows, and
A fluid inlet pipe 220 communicating with one side of the body part inserting part 210, through which fluid flows into the fluid inlet hole 112 of the rotor case 110,
It is in communication with the other side of the body portion insertion portion 210, characterized in that it comprises a fluid discharge pipe 230 through which the fluid flowing through the fluid flow path 211 is discharged
Circulating water meter.










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