KR20160069532A - Flow sensor body and flow sensor equipped with the flow sensor body - Google Patents

Abstract

The present invention relates to a flow sensor body capable of making a user selectively realize a switch type flow sensor and an impeller rotation detection type flow sensor with the same flow sensor body, and to a flower sensor using the same. A flow sensor body (100) according to an embodiment of the present invention comprises: a direct water supply body (110) including a direct water inlet (111) and a direct water outlet (112), a hollow unit (110a) connected to the direct water inlet (111) and direct water outlet (112) and an opening unit (113) formed in a side facing the direct water inlet (111); a lead switch mount unit (114) formed on one side of the direct water supply body (110) to make a lead switch (440) turning on/off in accordance with an approach of a magnetic (330) prepared to rotate by a flow of direct water flowing through the inside of the direct water supply body (110) be attached and detached; and a hall sensor mount unit (115) formed on the other side of the direct water supply body (110) to make a hall sensor (700) to detect the number of rotations of a blade (620) prepared to rotate by a flow of direct water flowing through the inside of the direct water supply body (110) be attached and detached, wherein a magnetic paddle mount member (200) to which the magnetic (330) is mounted or an impeller mount unit (500) to which the blade (620) is mounted is selectively inserted and coupled through the opening unit (113) into the hollow unit (110a).

Description

[0001] The present invention relates to a flow sensor body and a flow sensor having the flow sensor body,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow sensor body and a flow sensor having the flow sensor body. More particularly, the present invention relates to a flow sensor using a switch type flow sensor and an impeller rotational speed sensing method, To a sensor body and a flow sensor equipped with the sensor body.

Generally, a water heater or a boiler is provided with a flow sensor as means for detecting the flow and flow rate of direct or heating water and controlling the load of the combustion apparatus. The type of the flow sensor is classified into a switch type flow sensor and a flow rate sensor of the impeller rotational speed sensing method.

In the prior art relating to the switch type flow sensor, the registration 10-0342131 discloses a configuration of a flow sensor comprising a magnetic paddle located inside a pipe and a reed switch detecting the position of the magnetic paddle to detect the flow rate . The magnetic paddles are pivoted to a vertex of the hinge fixed to the inner wall of the pipe according to the flow rate of the fluid flowing inside the pipe, and the reed switch senses the pivotal position of the magnetic paddles to detect the flow rate flowing through the pipe.

In the prior art relating to the flow rate sensor of the impeller rotational speed sensing method, Japanese Patent Application Laid-Open No. 10-0619224 discloses an impeller installed in an outlet of a valve body, a plurality of magnets installed on a blade of the impeller, A sensor for detecting the flow rate of the impeller by sensing the rotational speed of the impeller with a magnetic field of the magnet is provided on the outer circumferential surface of the outlet.

The switch type flow sensor is configured in such a manner that the contact is turned on / off according to the flow of the fluid, so that only the flow of the fluid is detected. Therefore, the structure is simple and the manufacturing cost is low, The flow rate can not be accurately detected.

On the other hand, the flow sensor of the impeller rotational speed sensing method is configured to detect the rotational speed of the impeller according to the flow of the fluid, so that it is possible to simultaneously detect the flow rate and the flow rate of the fluid, There is a disadvantage in that the structure is complicated and the manufacturing cost is high.

Conventionally developed flow sensors are structured to be realized by only one of the above-mentioned two methods, so that users can not select any one of the two types of flow sensors according to the necessity of operation of the apparatus, There is a problem.

On the other hand, in the water heater or the boiler, the maximum supply flow rate of the fluid is limited to a predetermined value or less, thereby suppressing noise caused by the water hammer phenomenon caused when the flow rate is exceeded, and to increase the thermal efficiency A flow restrictor is installed.

According to the related art, in Patent Publication No. 10-0929210, a variable flow rate valve is installed in a water return pipe through which water is returned through a water return pipe in each room. When a room where heating is stopped occurs, Which is configured to regulate the total flow rate of the fluid. According to this, when the total amount of refining oil for each generation is controlled in proportion to the presence or absence of heating of each room, if there is a room where heating is not performed, noise generation and heating cost can be reduced by reducing the total amount of flow through the room.

However, in such a constant flow rate automatic control apparatus, the control unit controls the driving of the actuator that adjusts the opening amount of the variable flow rate valve by receiving signals from the temperature control unit installed in each room and a signal from a flow rate sensor installed in the water return pipe , The structure of the system for controlling the variable flow valve is complicated, and the installation cost of the system is high.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a flow sensor body capable of selectively implementing a switch type flow sensor and a flow rate sensor of the impeller rotational speed sensing type using one same flow rate sensor body, And it is an object of the present invention to provide a flow sensor equipped therewith.

It is another object of the present invention to provide a flow sensor body having a structure that can simplify the piping structure of the direct water flow path and the hot water flow path of the water heater to reduce the volume occupied by the piping and increase the productivity.

It is still another object of the present invention to provide a flow sensor having a flow restriction valve capable of reducing the unit price of the product and increasing the production amount by simplifying the structure of the flow restriction valve that limits the maximum supply amount of the fluid.

The flow sensor body 100 according to the present invention for realizing the above object is provided with a direct water inlet 111 and a direct water outlet 112 and is connected to the direct water inlet 111 and the direct water outlet 112 A direct water supply body 110 provided with a hollow portion 110a therein and having an opening 113 at a side opposite to the direct water inlet 111; The direct-supply body 110 is provided with a reed switch 400 which is turned on and off according to the proximity of the magnet 330 which is pivoted by the direct-flow hydraulic force passing through the inside of the direct- A reed switch mounting portion 114 formed on one side of the reed switch mounting portion 114; And a hole sensor 700 for sensing the number of revolutions of the blade 620 provided to be rotated by a direct flow force passing through the inside of the direct water supply body 110, The hollow portion 110a is formed with a magnetic paddle mounting member 200 on which the magnet 330 is mounted or an impeller mounting member 200 on which the blade 620 is mounted 500 are selectively inserted and coupled through the opening 113.

The reed switch mounting portion 114 and the hall sensor mounting portion 115 may be formed so as to penetrate one side portion of the direct water supply body 110 such that the reed switch 400 and the hall sensor 700 are slidably attached and detached, have.

The inner surface of the direct water supplying body 110 is provided with engaging protrusions 110b and 110c for fixing the position where the magnetic paddle mounting member 200 or the impeller mounting member 500 is inserted, (200) or a seat portion (110d) on which the impeller mounting member (500) is seated and supported.

A hot water supplying body 120 having a hot water inlet 121 and a hot water outlet 122 may be integrally formed with the direct water supplying body 110 at one side of the direct water supplying body 110.

The flow sensor 10 according to an embodiment of the present invention includes the flow sensor body 100; The magnetic paddle mounting member 200; A hinge portion 310 fixed to the inside of the magnetic paddle mounting member 200, a link member 320 having one end pivotally connected to the hinge portion 310, A magnetic paddle 300 made up of a magnet 330 attached to the magnet 300; And a reed switch 400 coupled to the reed switch mounting portion 114 and being turned on / off according to proximity of the magnet 330.

The flow sensor 20 according to another embodiment of the present invention includes a flow sensor body 100; The impeller mounting member 500; An impeller 600 comprising a rotating shaft 610 rotatably supported at an inner center of the impeller mounting member 500 and a plurality of blades 620 coupled to the outer surface of the rotating shaft 610 at regular intervals; And a Hall sensor 700 coupled to the Hall sensor mounting part 115 and sensing the number of revolutions of the blade 620.

In the above embodiments, a flow restriction valve 800 for limiting the supply amount of direct water is provided on the direct water inlet 111 side of the direct water supply body 110, A central pillar member 812 provided at an inner central portion of the cylindrical member 811 and a pillar member 812 formed at an inner side of the cylindrical member 811 and a A valve body (810) integrally formed with a connecting member (813) which connects the side surfaces and is arranged at regular intervals along the circumferential direction; And an elastic member 820 disposed between the inner surface of the cylindrical member 811 and the outer surface of the central pillar member 812 and deformed by the direct supply pressure to restrict the direct flow path.

A release preventing member 814 is formed on the outer surface of the central pillar member 812 to protrude at regular intervals along the circumferential direction to prevent the elastic member 820 from being detached from the cylindrical member 811 .

A flow distribution member 815 that forms a direct flow path is formed on the outer side surface of the central pillar member 812 so as to protrude at regular intervals along the circumferential direction and uniformly distribute direct water flowing in the circumferential direction of the central pillar member 812, May be integrally formed.

Guide ribs 811a protruding at regular intervals along the circumferential direction are integrally formed on the inner surface of the cylindrical member 811. Guide grooves 811b are formed between the neighboring guide ribs 811a, The guide ribs 811a and the guide grooves 811b are integrally formed with projecting pieces 811c and 811d projecting toward the central pillar member 812. The adjacent projecting pieces 811c and 811d are vertically So that a stepped portion is formed to form a direct flow path.

According to the flow sensor body and the flow sensor having the flow sensor body according to the present invention, the switch type flow sensor and the flow rate sensor of the impeller rotational speed sensing method can be selectively implemented using one same flow sensor body, When operating the boiler, you can select the type of flow sensor according to your needs.

Further, by integrally forming the direct water supply body and the hot water supply body in the flow sensor body, it is possible to simplify the piping structure of the direct water flow path and the hot water flow path of the water heater, thereby reducing the volume occupied by the piping and increasing the product productivity.

Further, since the flow rate limiting valve can be manufactured through a simple structure composed of the valve body integrally formed by injection molding and the elastic member inserted into the valve body, the cost of the product can be lowered, The configuration can be simplified.

1 is a perspective view of a flow sensor body 100 according to an embodiment of the present invention,
Fig. 2 is a plan view of Fig. 1,
3 is a sectional view taken along the line AA in Fig. 2,
4 is a perspective view of a flow sensor 10 according to an embodiment of the present invention,
Fig. 5 is a plan view of Fig. 4,
FIG. 6 is a sectional view taken along line BB in FIG. 5,
7 is a perspective view of a flow sensor 20 according to another embodiment of the present invention,
Fig. 8 is a plan view of Fig. 7,
9 is a sectional view taken along the line CC in Fig. 8,
10 is a perspective view of a flow restriction valve 800 provided in the flow sensor according to the present invention,
11 is an exploded perspective view of Fig. 10,
Fig. 12 is a bottom view of Fig. 10,
Fig. 13 is a plan view of Fig. 10,
Figs. 14 and 15 are sectional views along the line DD of Fig. 13 showing the operating state of the flow restriction valve 800 according to the change of the direct supply pressure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a flow sensor body 100 according to an embodiment of the present invention, FIG. 2 is a plan view of FIG. 1, and FIG. 3 is a sectional view taken along line A-A of FIG.

In the flow sensor body 100 of the present invention, a direct water supply body 110 formed on one side and a hot water supply body 120 formed on the other side are integrally injection-molded.

The direct water supply body 110 is formed with a direct water inlet 111 and a direct water outlet 112. The water is discharged to the hot water supply body 120 through the direct water discharge port 112 and passes through a heat exchanger A hot water inlet 121 through which heated hot water flows is formed at an upper portion and a hot water outlet 122 is formed at a lower portion.

The direct-supply body 110 has a direct-water inlet 111 formed at a lower portion thereof, a direct-discharge outlet 112 formed at an upper portion thereof, and an opening 113 formed at an upper portion thereof opposed to the direct- And a hollow portion 110a communicating with the direct water inlet 111 and the direct water outlet 112 to provide a direct flow path is provided therein.

The direct water supply body 110 has a switch type flow sensor and a mounting structure capable of selectively implementing a flow rate sensor of the impeller rotational speed sensing method.

A reed switch mounting portion 114 is formed on one side of the direct water supplying body 110 and a hall sensor mounting portion 115 is provided on the other side of the direct water supplying body 110. A reed switch 400 (see FIG. 6) is attached to or detached from the reed switch mounting portion 114, and a hall sensor 700 (see FIG. 9) is attached to or detached from the hall sensor mounting portion 115.

The reed switch mounting portion 114 and the hall sensor mounting portion 115 are formed by horizontally penetrating one side portion of the direct supply body 110 so that the reed switch 400 and the hall sensor 700 are detachably mounted in a sliding manner have.

6) or an impeller mounting member 500 (see FIG. 9) are selectively inserted into the hollow portion 110a provided in the direct-supply body 110, do.

The reed switch 400 is mounted on the reed switch mounting portion 114 and the magnetic paddle mounting member 200 is coupled to the hollow portion 100a so that the switch type flow sensor 10 See FIG. In another embodiment, when the hall sensor 700 is mounted on the hall sensor mounting portion 115 and the impeller mounting member 500 is coupled to the hollow portion 100a, the flow sensor 20 , See Fig. 9) is implemented.

On the inner surface of the direct water supply body 110, the engagement pawls 110b and 110c for fixing the position where the magnetic paddle mounting member 200 or the impeller mounting member 500 are inserted are vertically spaced And a magnetic paddle mounting member 200 or a seat portion 110d in which the impeller mounting member 500 is seated and supported is formed at the lower portion. A coupling member insertion hole 116 into which the magnetic paddle mounting member 200 or the coupling member 117 for fixing the impeller mounting member 500 is inserted is formed on both sides of the upper portion of the direct water supplying body 110, In the front-rear direction.

Reference numeral 18 denotes a replenishing water supply port for replenishing the running water with heating water when the heating water of the boiler connected to the water heater is insufficient.

According to the flow sensor body 110 of the present invention configured as described above, the switch type flow rate sensor 10 and the flow rate sensor 20 for detecting the rotational speed of the impeller can be selectively implemented in the direct supply body 110 The flow sensor body 100 can be formed with the water supply body 110 and the hot water supply body 120 integrally by injection molding, And the piping structure of the hot water flow path can be simplified.

The configuration and operation of the switch type flow sensor 10 using the flow sensor body 100 constructed as described above and the flow sensor 20 of the impeller rotational speed detection method will be described below. First, the configuration and operation of the switch type flow sensor 10 will be described.

FIG. 4 is a perspective view of a flow sensor 10 according to an embodiment of the present invention, FIG. 5 is a plan view of FIG. 4, and FIG. 6 is a sectional view taken along line B-B of FIG.

The switch type flow sensor 10 includes the flow sensor body 100 and the magnetic paddle mounting member 200 inserted into the hollow portion 110a through the opening 113 of the flow sensor body 100, A magnetic paddle 300 mounted on the magnetic paddle mounting member 200 and a reed switch 400 coupled to the reed switch mounting portion 114. The magnetic paddle mounting member 200 includes a cylindrical body portion 210 having a direct flow path formed therein, a handle 220 protruding upward from the upper portion of the body portion 210, And a direction indicator 230 provided on one side of the upper part of the upper case 210.

A lower portion of the body 210 is formed to communicate with the direct water inlet 111 and an opening 210a is formed in the upper portion of the body 210 to communicate with the direct water outlet 112. A coupling member insertion groove 211 into which a coupling member 117 for fixing the magnetic paddle mounting member 200 in a coupled state is inserted into an outer circumferential surface of the upper portion of the body portion 210 and an O- An O-ring engagement groove 212 is formed.

The handle 220 functions to allow the user to grasp the magnetic paddle mounting member 200 when the magnetic paddle mounting member 200 is attached to or detached from the hollow portion 110a of the direct supply body 110, .

The direction indicator 230 functions to direct the direction of the magnetic paddle mounting member 200 so that the magnetic paddle mounting member 200 can be positively positioned inside the hollow portion 110a.

The magnetic paddle 300 includes a hinge portion 310 fixed to the inside of the body portion 210, a link member 320 having one end pivotally connected to the hinge portion 310, A magnet 330 attached to one side of the magnet 330 and a cover 340 surrounding the magnet 330. The hinge part 310 may be coupled with an elastic means (not shown) for providing an elastic force in a direction in which the magnetic 330 is separated from the reed switch 400.

Therefore, when the direct water does not flow, the magnet 330 is separated from the reed switch 400, and the reed switch 400 is turned off. When the direct water is introduced through the direct water inlet 111, the link member 320 and the magnet 330 attached to the link member 320 are pivoted upward by the direct flow force larger than the elastic force of the elastic means, The reed switch 400 is turned on by the magnetism of the magnet 300 and the reed switch 400 is turned on by the on state of the reed switch 400 The burning operation of the burner is performed.

On the other hand, a flow restriction valve 800 for limiting the maximum supply amount of direct water flowing through the direct water inlet 111 is coupled to the lower portion of the magnetic paddle mounting member 200, and a specific configuration thereof will be described later.

Next, the configuration and operation of the flow sensor 20 of the impeller rotational speed sensing method will be described. FIG. 7 is a perspective view of a flow sensor 20 according to another embodiment of the present invention, FIG. 8 is a plan view of FIG. 7, and FIG. 9 is a sectional view taken along line C-C of FIG.

The flow sensor 10 of the impeller rotational speed sensing method includes the flow sensor body 100 and the impeller mounting member 100 inserted into the hollow portion 110a through the opening 113 of the flow sensor body 100, An impeller 600 mounted on the impeller mounting member 500 and a hall sensor 700 coupled to the hall sensor mounting portion 115. [

The impeller mounting member 500 includes a cylindrical body portion 510 having a direct flow path formed therein, a handle 520 protruding upward from the upper portion of the body portion 510, And a direction indicator 530 provided at one side of the upper portion of the upper portion 510.

The lower portion of the body portion 510 is formed to communicate with the direct water inlet 111 and the opening portion 510a is formed at one side of the upper portion of the body portion 510 to communicate with the direct water outlet 112. A coupling member insertion groove 511 into which a coupling member 117 for fixing the impeller mounting member 500 in a coupled state is inserted and an O-ring 513 for preventing water leakage are coupled to the outer peripheral surface of the upper portion of the body portion 510 An O-ring engagement groove 512 is formed.

The handle 520 and the direction indicator 530 may have the same structure as the handle 220 and the direction indicator 230 of the above-described embodiment.

The impeller 600 includes a rotating shaft 610 rotatably disposed at an inner center of the impeller mounting member 500, a plurality of blades 620 coupled to the outer surface of the rotating shaft 610 at regular intervals, (Not shown) is attached to a part or the whole of the plurality of blades 620. The rotation shaft supporting portions 611 and 612 rotatably support both ends of the rotation shaft 610.

Therefore, when the direct water is introduced through the direct water inlet 111, the blade 620 is rotated about the rotational axis 610 by the direct flow force, and the hall sensor 700 is rotated around the rotational axis 610, The rotational speed of the blade 620 is sensed by the magnetic properties of the nets, and the flow rate of the direct water is detected on the basis of the rotational speed to control the burning amount of the burner.

A flow restriction valve 800 for limiting the maximum supply amount of direct water flowing through the direct water inlet 111 is coupled to the lower portion of the impeller mounting member 500 via a flow restriction valve mounting member 900 .

Hereinafter, the configuration and operation of the flow rate limiting valve 800 will be described.

Fig. 10 is a perspective view of a flow restriction valve 800 provided in the flow sensor according to the present invention, Fig. 11 is an exploded perspective view of Fig. 10, Fig. 12 is a bottom view of Fig. FIG. 15 is a sectional view along the DD line of FIG. 13 showing the operating state of the flow restriction valve 800 according to the change of the supply pressure of the direct water.

The flow rate limiting valve 800 includes a valve body 810 integrally formed by injection molding and an elastic member 810 which is inserted inside the valve body 810 and deformed by a direct supply pressure, Member 820 as shown in Fig.

The valve body 810 includes a cylindrical member 811 having a direct flow path formed therein, a central pillar member 812 provided at an inner central portion of the cylindrical member 811, And a connecting member 813 which connects the side surfaces and the outer surface of the central pillar member 812 at predetermined intervals along the circumferential direction.

The elastic member 820 is inserted between the inner surface of the cylindrical member 811 and the outer surface of the central pillar member 812 and the elastic member 820 is pushed toward the connecting member 813 when the direct water is introduced And is in close contact with the connecting member 813.

A release preventing member 814 protruding at a predetermined interval along the circumferential direction is provided on the lower outer side surface of the central pillar member 812 to prevent the elastic member 820 from being detached from the cylindrical member 811 . In the present embodiment, the release preventing members 814 are formed on the outer surface of the central pillar member 812 at intervals of 90 degrees.

The outer surface of the central pillar member 812 is protruded from the release preventing member 814 at regular intervals along the circumferential direction to form a space between the inner surface of the cylindrical member 811 and the outer surface of the central pillar member 812, The flow rate distribution member 815 is formed so that the direct water flowing into the center column member 812 is uniformly distributed in the circumferential direction of the central pillar member 812. Since the direct water is uniformly distributed in the circumferential direction by the flow distribution member 815 and passes through the flow rate restriction valve 800, direct flow of water can be performed smoothly, thereby reducing noise generation. In the present embodiment, the flow rate distribution members 815 are formed on the outer surface of the central pillar member 812 at intervals of 30 degrees.

A guide rib 811a is formed on the inner side surface of the cylindrical member 811 at predetermined intervals along the circumferential direction, and between adjacent guide ribs 811a, A guide groove 811b is formed.

A projecting piece 811c protruding in a predetermined length toward the central axis of the central pillar member 812 is formed at the upper end of the guide rib 811a and the central pillar member 812 is formed in the upper end of the guide groove 811b. A protruded piece 811d protruding in a predetermined length toward the center of the protrusion 811d. A protruding piece 811c extending from the guide rib 811a and a protruding piece 811d extending from the neighboring guide groove 811b are formed so as to intersect with each other in the vertical direction, (816).

In this embodiment, the guide ribs 811a and the guide grooves 811b and the protruding pieces 811c and 811d extending from the upper ends of the guide ribs 811a and 811b are formed at intervals of 30 ° in the circumferential direction, The protruding piece 811c and the connecting member 813 are formed at the same height so that the elastic member 820 is in close contact with the protruding piece 811c and the connecting member 813. [ A protrusion 811e is formed on the inner surface of the guide rib 811a to be in close contact with the outer surface of the elastic member 820 in order to prevent the elastic member 820 from coming off.

Hereinafter, the operation of the flow rate limiting valve 800 according to the direct supply pressure will be described with reference to Figs. 14 and 15. Fig.

14, since the cross section of the elastic member 820 is close to the circular shape as shown in FIG. 14, the flow path through which the direct water flows passes through the elastic member 820 and the center column member 820, The space between the outer side surfaces of the elastic member 812 and the inner side surface of the elastic member 820 and the inner surface of the cylindrical member 811,

On the other hand, when the direct water pressure exceeds a predetermined pressure, the elastic member 820 is deformed into a flat elliptical shape by the direct supply pressure as shown in FIG. 15, Since the flow path is limited to a space defined between the outer surface of the central pillar member 812 and the outer surface of the central pillar member 812, the flow rate of the direct water flowing therethrough is limited to a certain amount or less.

The flow rate limiting member 800 configured as described above is automatically limited so that the supply amount of the direct water becomes equal to or less than the set maximum supply amount thereby to prevent the noise from the piping due to the cavitation caused by the concentrated supply of the direct water, By limiting the supply of direct water below the flow rate, stable operation of the water heater becomes possible.

Although the present invention has been described by way of example in the context of the present invention in which the flow sensor senses the flow rate of the direct water flowing into the water heater, the scope of application of the present invention is not limited thereto. It can be widely applied to various apparatuses.

10, 20: Flow sensor 100: Flow sensor body
110: direct water supply body 110a: hollow part
110b, 110c: engagement stopper 110d:
111: direct water inlet 112: direct water outlet
113: opening 114: reed switch mounting portion
115: Hall sensor mounting portion 116: Fastening member insertion hole
117: fastening member 118: replenishing water supply port
120: hot water supply body 121: hot water inlet
122: Hot water outlet 200: Magnetic paddle mounting member
210: Body part 210a:
211: fastening member insertion groove 212: O-ring engagement groove
213: O-ring 220: Handle portion
230: Direction indicator 300: Magnetic paddle
310: Hinge 320: Link member
330: Magnetic 340: cover
400: Reed switch 500: Impeller mounting member
510: body portion 511: fastening member insertion groove
512: O-ring coupling groove 513: O-ring
520: handle 530: direction indicator
600: Impeller 610:
611, 612: rotatable shaft support part 620: blade
700: Hall sensor 800: Flow restriction valve
810: valve body 811: cylindrical member
811a: Guide rib 811b: Guide groove
811c, 811d: protruding piece 811e:
812: central pillar member 813: connecting member
814: Release preventing member 815: Flow distributing member
816: Direct water passing hole 820: Elastic member
900: Flow limiting valve mounting member

Claims (10)

A hollow portion 110a communicating with the direct water inlet 111 and the direct water outlet 112 is provided therein and the water inlet 111 and the direct water outlet 112 are opposed to the direct water inlet 111, A direct water supply body 110 provided with an opening 113;
The direct-supply body 110 is provided with a reed switch 400 which is turned on and off according to the proximity of the magnet 330 which is pivoted by the direct-flow hydraulic force passing through the inside of the direct- A reed switch mounting portion 114 formed on one side of the reed switch mounting portion 114; And
And a hole sensor 700 for sensing the rotational speed of the blade 620 that is rotated by the direct flow force passing through the inside of the direct water supply body 110 is attached to the other side of the direct water supply body 110 And a hole sensor mounting portion (115) formed thereon,
The magnetic paddle mounting member 200 on which the magnetic 330 is mounted or the impeller mounting member 500 on which the blade 620 is mounted is selectively inserted into the hollow portion 110a through the opening portion 113, (100). ≪ / RTI > The method according to claim 1,
The reed switch mounting portion 114 and the hall sensor mounting portion 115 are formed so as to penetrate one side portion of the direct water supply body 110 so that the reed switch 400 and the hall sensor 700 are slidably mounted and detached, respectively (100). ≪ / RTI > The method according to claim 1,
The inner surface of the direct water supplying body 110 is provided with engaging protrusions 110b and 110c for fixing the position where the magnetic paddle mounting member 200 or the impeller mounting member 500 is inserted, And a seat portion (110d) on which the impeller mounting member (200) or the impeller mounting member (500) is seated and supported. The method according to claim 1,
Wherein a hot water supply body 120 having a hot water inlet 121 and a hot water discharge port 122 is integrally formed with the direct water supply body 110 at one side of the direct water supply body 110. [ (100). A flow sensor body (100) according to claim 1;
The magnetic paddle mounting member 200;
A hinge portion 310 fixed to the inside of the magnetic paddle mounting member 200, a link member 320 having one end pivotally connected to the hinge portion 310, A magnetic paddle 300 made up of a magnet 330 attached to the magnet 300; And
And a reed switch (400) coupled to the reed switch mounting portion (114) and turned on / off according to proximity of the magnet (330). A flow sensor body (100) according to claim 1;
The impeller mounting member 500;
An impeller 600 comprising a rotating shaft 610 rotatably supported at an inner center of the impeller mounting member 500 and a plurality of blades 620 coupled to the outer surface of the rotating shaft 610 at regular intervals; And
And a Hall sensor (700) coupled to the Hall sensor mounting part (115) and sensing the number of rotations of the blade (620). The method according to claim 5 or 6,
A flow restriction valve 800 for limiting the supply amount of direct water is provided on the direct water inlet 111 side of the direct water supply body 110,
The flow rate limiting valve (800)
A central pillar member 812 provided at an inner central portion of the cylindrical member 811 and an inner side surface of the cylindrical member 811 and a central pillar member 812 A valve body 810 integrally formed with a connecting member 813 provided at regular intervals along the circumferential direction; And
And an elastic member (820) provided between the inner surface of the cylindrical member (811) and the outer surface of the central pillar member (812) and deformed by the direct supply pressure to restrict the direct flow path. 8. The method of claim 7,
The outer side surface of the central pillar member 812 is integrally formed with a release preventing member 814 protruding at a predetermined interval along the circumferential direction to prevent the elastic member 820 from being separated from the cylindrical member 811 And a flow sensor. 8. The method of claim 7,
A flow distribution member 815 that forms a direct flow path is formed on the outer side surface of the central pillar member 812 so as to protrude at regular intervals along the circumferential direction and uniformly distribute direct water flowing in the circumferential direction of the central pillar member 812, ) Are integrally formed. 8. The method of claim 7,
Guide ribs 811a protruding at regular intervals along the circumferential direction are integrally formed on the inner surface of the cylindrical member 811. Guide grooves 811b are formed between the neighboring guide ribs 811a, The guide ribs 811a and the guide grooves 811b are integrally formed with projecting pieces 811c and 811d projecting toward the central pillar member 812. The adjacent projecting pieces 811c and 811d are vertically So that a flow path of a direct flow is formed.

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