KR102424548B1 - A manual control valve install structure of hot water distributor - Google Patents

Abstract

The present invention relates to a manual control valve installation structure of a hot water distributor, and more particularly, the cap tube is designed and provided in the same structure, and the valve tube opening and closing method according to screw rotation is applied to simplify the configuration and mechanical lifespan for airtightness By allowing this to be extended, it relates to a structure for installing a manual control valve of a hot water distributor so that manufacturing costs and maintenance costs can be reduced.
To this end, a main pipe forming a main pipe through which heating water is introduced or returned from one side; a lower pipe part that is installed toward the lower side of the main pipe and is branched from the main pipe to form a lower pipe for supplying hot water to each room or returning the hot water circulating in each room; a valve part formed between the lower pipe line and the main pipe line and including a valve pipe line communicating the lower pipe line and the main pipe line, and formed to be exposed toward the front of the cap pipe; and a control valve installed to be detachably from the valve unit and provided to open and close the valve conduit, wherein the control valve includes: a body installed detachably from the valve unit; an elastic member installed on the body and installed to face the valve conduit; It is screw-coupled to the body and includes a handle for closing the valve conduit by pushing the elastic member through screw rotation, wherein the valve conduit includes: a first passage formed to communicate in the same direction as the lower conduit; a second flow path for converting the heating water transfer direction of the first flow path toward the front of the cap tube; It is formed between the main pipe and the second flow path, and includes a third flow path that forms a flow path toward the front of the main pipe in a direction perpendicular to the main pipe, wherein the valve pipe allows heating water to flow in a straight line. Rather, it is configured so that the flow of heating water can be switched, and is configured to be biased to one side of the cap pipe together with the lower pipe pipe, so that the cap pipe can be manufactured only with the primary mold. Provides a manual control valve installation structure for a hot water distributor do.

Description

A manual control valve install structure of hot water distributor

The present invention relates to a structure for installing a manual control valve for a hot water distributor, and more particularly, to a structure for installing a manual control valve for a hot water distributor including a manual control valve that can reduce the cost of manufacturing a capillary and maintain airtightness even after long use. is about

In general, the residential heating structure in Korea heats the floor by introducing hot water heated by the boiler into the heating pipes of each room, so that the warm air in the lower part that comes into contact with the floor rises, and the cold air in the upper falls down to the floor. Heating is performed by generating convection. In this Korean-style residential heating system, an individual heating system that controls heating for each room in the household is applied to prevent excessive waste of heating energy. To this end, the heating system includes a hot water distributor for branching the heating water provided by the boiler to each room. That is, the hot water distributor serves to supply and circulate the hot water produced in the boiler to the area requiring heating or to block the supply circulation of the hot water to the area that does not require heating. At this time, the hot water distributor is required together with a valve controller for controlling the opening and closing of the valve and a temperature controller installed in each room.

As shown in FIG. 1, the hot water distributor has a supply pipe 2 and a return pipe 3 installed in the transverse direction between the side plates 1 erected on both sides, and the supply pipe 2 and the return pipe 3 have heating. A hot water branch pipe (4) branching to each required room or living room is provided. At this time, a pipe (P) is connected to the hot water branch pipe (4), and a control valve for controlling the hot water outlet to each room is installed in the hot water branch pipe (4). As shown in FIG. 1 , the control valve is provided with a solenoid valve (S) installed in the return pipe (3) and a ball valve (10) installed in the hot water branch pipe (4) in the supply pipe (2). The ball valve 10 is a mediating means for connecting a plurality of pipes P to the supply pipe 2 and is configured to control the amount of hot water supplied.

As shown in FIG. 2, the ball valve 10 installed in the supply pipe 2 has a handle 11 and an inner passage 13 that is opened and closed by a rotating body 12 that is rotated by the handle 11. Consists of a tubular body (14). At this time, sealing members 15 for sealing the inner passage 13 are respectively installed on both sides of the rotating body 12 . In addition, a screw thread for screw coupling with the supply pipe 2 is formed on one side of the ball valve 10 , and a screw coupling part 16 for coupling with the pipe P is provided on the other side of the ball valve 10 . . The screwed portion 16 includes a union nut 16a, and the pipe P is coupled to the screwed portion 16 through tightening of the union nut 16a.

In the conventional hot water distributor having the above configuration (10) due to friction with the sealing member 15 according to the rotation of the rotating body 12, the sealing member 15 is worn, and the rotating body 12 is moved to the inner passage 13 ), there is a problem that leakage may occur even if it is closed.

In particular, there is a problem that the ball valve 10 is not suitable for adjusting the flow rate by gradually opening the inner passage 13 . That is, since the ball valve 10 uses a circular sealing member 15, only a part of the sealing member 15 receives water pressure in a state in which the inner passage 13 is slightly opened. Deformation may occur, and the conventional hot water distributor may cause leakage problems due to deformation of the sealing member 15 .

In addition, the conventional hot water distributor has a problem in that the solenoid valve (S) coupling structure of the return pipe (3) and the ball valve (10) coupling structure of the supply pipe (2) are different, so that the manufacturing cost is increased.

Republic of Korea Registration No. 10-0974004

The present invention has been devised to solve the above problems, and an object of the present invention is to reduce the manufacturing cost of the cap pipe by making the design of the supply pipe and the return pipe the same, and screw rotation the opening/closing method of the manual control valve that controls the water outlet of the supply pipe. This is to provide a structure for installing a manual control valve for a hot water distributor so that the airtightness of the manual control valve can be maintained for a long time by applying this type, and the manufacturing cost of the manual control valve can be reduced.

The present invention, in order to achieve the above object, a main pipe forming a main pipe through which heating water is introduced or returned from one side; a lower pipe part that is installed toward the lower side of the main pipe and is branched from the main pipe to form a lower pipe for supplying hot water to each room or returning the hot water circulating in each room; a valve part formed between the lower pipe line and the main pipe line and including a valve pipe line communicating the lower pipe line and the main pipe line, and formed to be exposed toward the front of the cap pipe; and a control valve installed to be detachably from the valve unit and provided to open and close the valve conduit, wherein the control valve includes: a body installed detachably from the valve unit; an elastic member installed on the body and installed to face the valve conduit; It is screw-coupled to the body and includes a handle for closing the valve conduit by pushing the elastic member through screw rotation, wherein the valve conduit includes: a first passage formed to communicate in the same direction as the lower conduit; a second flow path for converting the heating water transfer direction of the first flow path toward the front of the cap tube; It is formed between the main pipe and the second flow path, and includes a third flow path that forms a flow path toward the front of the main pipe in a direction perpendicular to the main pipe, wherein the valve pipe allows heating water to flow in a straight line. Rather, it is configured so that the flow of heating water can be switched, and is configured to be biased to one side of the cap pipe together with the lower pipe pipe, so that the cap pipe can be manufactured only with the primary mold. Provides a manual control valve installation structure for a hot water distributor do.

At this time, a screw groove facing the front of the capillary is formed in the valve part, and a coupling hole is formed in a portion corresponding to the screw groove in the body, and a fastening screw capable of being screwed into the screw groove through the coupling hole is formed. It is preferable to provide

In this case, the body includes a first cover having a first coupling hole corresponding to the screw groove of the valve part, and having a central through hole through both sides in the center; a second cover coupled to the first cover, the second cover having a second coupling hole corresponding to the first coupling hole, and having a screw hole having a smaller diameter than the diameter of the central through hole; It is preferable to include a handle screwed to the screw hole so as to move straight toward the central hole, and the elastic member is installed in the central hole to close the valve pipe while being pushed through the screw rotation of the handle. .

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In this case, the elastic member is preferably configured to open and close the third flow path.

In addition, it is preferable that the control valve is installed in the valve part of the supply pipe, and an automatic control valve for automatically opening and closing the valve pipe of the return pipe is installed in the return pipe.

The manual control valve installation structure of the hot water distributor according to the present invention has the following effects.

First, the manual control valve installation structure of the hot water distributor includes a manual control valve that opens and closes a pipe through screw rotation, and the manual control valve does not cause wear of parts due to rotational friction. Accordingly, the manual control valve installation structure of the hot water distributor has the effect of maintaining the airtight force of the manual control valve for a long time. Furthermore, the manual control valve installation structure of the hot water distributor has the effect of reducing the cost of the manual control valve maintenance.

Second, the manual control valve installation structure of the hot water distributor is provided with a resin material and has the effect of reducing the manufacturing cost by simplifying the configuration.

Third, the manual control valve installation structure of the hot water distributor has the effect of reducing the manufacturing cost of the hot water distributor because the supply pipe and the return pipe can be designed and provided in the same way.

1 is a view showing a hot water distributor according to the prior art from the front.
2 is a cross-sectional view showing a manual control valve of a hot water distributor according to the prior art.
3 is a view showing the installation structure of the manual control valve of the hot water distributor according to a preferred embodiment of the present invention.
4 is an exploded perspective view showing a manual control valve of a manual control valve installation structure of a hot water distributor according to a preferred embodiment of the present invention.
5 is a perspective view showing a manual control valve of a manual control valve installation structure of a hot water distributor according to a preferred embodiment of the present invention.
6 is a cross-sectional view showing a manual control valve of a manual control valve installation structure of a hot water distributor according to a preferred embodiment of the present invention.
7A and 7B are cross-sectional views showing the opening and closing action of the manual control valve installation structure of the hot water distributor according to a preferred embodiment of the present invention.

The terms or words used in the present specification and claims are not to be construed as limited in their ordinary or dictionary meanings, and on the principle that the inventor may appropriately define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Hereinafter, a manual control valve installation structure of a hot water distributor according to a preferred embodiment of the present invention will be described with reference to the accompanying FIGS. 3 to 7b.

The manual control valve installation structure of the hot water distributor made it possible to manufacture the supply pipe and the return pipe in the same way, and in particular, the configuration of the manual control valve installed in the supply pipe was simplified and the airtightness was not reduced even after long use. Accordingly, it is possible to reduce the manufacturing cost of the hot water distributor, and it is possible to reduce the maintenance cost of the manual control valve.

As shown in FIG. 3, in the manual control valve installation structure of the hot water distributor, a return pipe 100A and a supply pipe 100B are installed between a pair of brackets 1 in the up and down directions, and each return pipe ( 100A) and the supply pipe 100B are provided with a valve part 300 and a control valve for opening and closing the valve part 300 . For convenience of description, in the present specification, the return pipe and the supply pipe are referred to as the capillary 100 . The cap tube 100 is designed and provided in the same way, and a control valve is preferably installed as an automatic control valve (S) in the return pipe (100A) to easily control the heating ON/OFF. In this case, a solenoid valve may be provided as an example of the automatic control valve (S). On the other hand, a control valve is installed in the supply pipe 100B as a manual control valve 400, and the manual control valve 400 is configured to allow a worker to manually open and close the supply pipe for hot water distributor maintenance work. .

The manual control valve installation structure of the hot water distributor includes a cap tube 100 , a lower pipe portion 200 , a valve portion 300 , and a control valve 400 as shown in FIG. 3 .

The capillary 100 forms a main pipe 110 to which heating water is supplied, and is provided as a circular pipe. Threads are formed on both sides of the capillary 100 so that the closing cap for fixing to the bracket 1 can be screwed. The capillary 100 may be any material that can be injection molded through a mold. The capillary 100 is formed in the same way on both sides of the capillary 100 in order to increase the convenience of injection molding.

The lower pipe part 200 is a pipe through which heating water is supplied to each room, and is provided in the lower part of the main pipe 100 . The lower pipe part 200 forms a lower pipe line 210 branched from the main pipe line 110 , and the lower pipe line 210 is formed to communicate with a valve pipe to be described later, respectively. It is preferable that a thread is formed in the lower pipe part 200 so that a pipe for supplying heating water to each room can be screwed. On the other hand, the lower pipe line 210 of the lower pipe part 200 is formed at a position biased to one side with respect to the center of the main pipe line 110 of the cap pipe 100 . This is in order to be integrally formed during injection molding of the capillary 100, and when injection molding through a mold, the valve pipe 310 of the valve 300 and the lower pipe 210 of the lower pipe 200 are parting lines. Since it is integrally formed without the need for injection molding, it is possible to increase the convenience of injection molding. That is, since the lower pipe part 200 and the valve part 300 are designed to be biased to one side with respect to the center of the main pipe line 110 of the main pipe 100, there is no interference in the main pipe line 110. After injection molding, the molded product Separation can be done easily. If a separate pipe structure (conventional flow guide) is provided in the center of the main pipe 110 to form a pipe, it is impossible to separate the molded product after injection molding, so after the flow guide is manufactured according to the secondary mold, the cap pipe 100 Since the process of coupling the flow guide and the flow guide is further required, in the present invention, injection molding can be easily performed with only the primary mold due to the biased configuration of the valve part 300 and the lower pipe part 200 . On the other hand, it is preferable that the reinforcing ribs 200a are formed in the lower pipe part 200 as shown in FIG. 3 . A metal connecting means is coupled to the lower pipe part 200, and the reinforcing rib 200a increases the durability of the lower pipe part 200 made of resin, thereby damaging the lower pipe part 200 in the process of connecting the metal connecting means. This is to prevent this from happening. The reinforcing rib 200a is preferably in the form of a cross that crosses the lower conduit 210 .

The valve unit 300 provides a conduit for controlling the inflow of the heating water returned through the lower conduit 210 into the main conduit 110 . That is, the valve unit 300 is configured such that a control valve 400 to be described later opens and closes the valve conduit 310 to turn on/off heating. As shown in FIG. 3 , the valve unit 300 is installed in plurality on the front surface of the cap tube 100 when the hot water distributor is viewed from the front. The valve part 300 having such a configuration forms a pipeline perpendicular to the lower pipeline 210 . The valve part 300 is preferably provided with a screw groove (300a) so that the control valve 400 can be detached. The valve conduit 310 of the valve unit 300 communicates the main conduit 110 and the lower conduit 210, and as shown in FIG. 7a, a first channel 311 and a second channel 312, and a third flow path 313 . As described above, the valve unit 300 is provided to be biased toward one side of the cap tube 100 in order to increase the convenience and quality of injection molding of the cap tube 100 and reduce the cost of manufacturing the cap tube 100 . This can be understood through FIG. 7A.

The first flow path 311 of the valve conduit 310 forms a flow path communicating with the lower conduit 210 as shown in FIG. 7A , and the heating water introduced through the lower conduit 210 is transferred to the second flow path 312 . Euro to guide you to The first flow path 311 faces downward of the capillary 100 and is formed in a straight line with the lower pipe 210 . The first flow path 311 forms a guide wall W for guiding the heating water to the second flow path 312 . The guide wall W is preferably provided at a right angle toward the second flow path 312 . The second flow path 312 is a flow path for changing the direction of the heating water flowing in from the first flow path 311 toward the front of the hot water distributor. The third flow path 313 communicates with the main pipe 110 , and is a flow path for discharging the heating water of the second flow path 312 to the main pipe 110 . The third flow path 313 is formed in the same direction as the second flow path 312 , but the flow direction of the heating water is opposite. Such a valve pipe line 310 does not allow the heating water to flow in a straight line, but is configured so that the flow of heating water can be switched. There is an advantage that it can be configured to be biased to one side. This configuration can increase the convenience of manufacturing a mold for injection molding the cap tube 100, so that the cap tube can be manufactured with only the primary mold. This has the advantage of reducing the production cost of the cap tube.

The control valve 400 opens and closes the valve pipe line 310 to control the supply of heating water from the main pipe line 110 . The control valve 400 is preferably provided manually, and has a configuration provided so that the operator can arbitrarily control the hot water distributor during maintenance work. As shown in FIG. 4 , the control valve 400 includes a body 410 , an elastic member 420 , and a handle 430 .

The body 410 of the control valve 400 is provided to be detachably attached to the valve part 300 , and is preferably composed of a first cover 411 and a second cover 412 . The first cover 411 is configured to be in close contact with the valve part 300 , and forms a central through hole 411a corresponding to the valve conduit 310 . An elastic member 420 to be described later is positioned in the central through-hole 411a, and the elastic member 420 is configured to close the valve conduit 310 while expanding out of the central through-hole 411a. A stepped 411b is formed on the inner circumferential surface of the central through hole 411a so that the elastic member 420 can be seated and installed. A first coupling hole 411c corresponding to the screw groove 300a formed in the valve part 300 is formed in the first cover 411 . The second cover 412 is combined with the first cover 411 to constitute the body 410 , and a screw hole 412a for screwing the handle 430 is formed in the center. The diameter of the screw hole 412a is formed smaller than the diameter of the central through hole 411a. The screw hole 412a forms a seating groove 412b as shown in FIG. 6 . The seating groove portion 412b serves to prevent the handle 430 from being separated from the second cover 412 . The seating groove 412b is formed to have a larger diameter than the diameter of the screw hole 412a. Accordingly, the seating groove 412b has a stepped 412c between the screw hole 412 and the screw hole 412a. This step 412c interferes with the handle 430 and serves as a stopper to prevent the handle 430 from being separated. A second coupling hole 412d is also formed in the second cover 412 , and the second coupling hole 412d corresponds to the first coupling hole 411c. The coupling between the first cover 411 and the second cover 412 may be made through the fastening hole H shown in FIG. 4 .

The elastic member 420 of the control valve 400 is configured to open and close the valve conduit 310, and as can be seen from the name, it is provided with a material having an elastic force. Preferably, it may be provided in a soft material such as rubber or silicone. The elastic member 420 precisely opens and closes the third flow path 313 of the valve pipe 310 to prevent the heating water from being discharged from the main pipe line 110 to the lower pipe line 210 or to let the heating water flow out. The central portion of the elastic member 420 forms a contact portion 421 having a thickness formed thicker than the thickness outside the center of the elastic member 420, and the diameter of the contact portion 421 is the seating groove portion 412b of the second cover 412. corresponds to The contact portion 421 is provided to close the third passage 313 by being in close contact with the third passage 313 while being pushed out of the seating groove 412b through the movement of the handle 430 . It is preferable that the close contact portion 421 is further spaced apart from the edge of the elastic member 420 with respect to the valve portion 300 . This is to increase the tension of the adhesion part 421 to increase adhesion with the valve part 300 .

The handle 430 of the control valve 400 moves the elastic member 420 to cause the elastic member 420 to close the third flow path 313 . The handle 430 is screwed to the screw hole 412a of the second cover 412 , and a gripping portion 431 for facilitating gripping the handle 430 is formed at one end of the handle 430 . Meanwhile, the other end of the handle 430 is positioned in the seating groove 412b and is formed to have a diameter corresponding to the diameter of the seating groove 412b. The other end of the handle 430 is in close contact with the contact portion 421 , and is a portion that pushes the contact portion 421 when the handle 430 rotates.

Meanwhile, a closing cap 500 for coupling the capillary 100 to the bracket 1 is provided. As shown in FIG. 3, the closing cap 500 has a central portion 510 having both sides penetrated and a communication hole 511 communicating with the main tube 110 of the capillary 100, and the outer circumference of the central portion 510, as shown in FIG. Accordingly, the coupling portion 520 is formed. A female screw is formed on the inner circumferential surface of the coupling part 520 to be screwed to both male screws of the cap tube 100 . That is, the inner diameter of the coupling portion 520 corresponds to the outer diameter of the capillary 100 . The central part 510 is configured to be inserted into the main pipe line 110 of the cap tube 100 , and forms a communication hole 511 for recovering heating water from the cap pipe 100 . As both sides of the communication hole 511 are formed through, the heating water may be recovered from the main pipe 110 of the main pipe 100 . The outer diameter of the central portion 510 corresponds to the inner diameter of the main conduit 110 , and a female screw is formed on the inner circumferential surface of the communication hole 511 . On the other hand, one side of the main pipe 110 of the main pipe 100 is a path through which heating water is recovered, but the other side of the main pipe 110 must be closed. To this end, of the closing cap 500 coupled to the other side of the capillary 100, a stopper (not shown) capable of closing the communication hole 511 is coupled. The outer diameter of the stopper corresponds to the inner diameter of the communication hole 511, and an external thread is formed on the outer circumferential surface of the stopper. That is, the inner circumferential surface of the communication hole 511 is formed with a female screw, and the stopper is screwed to the communication hole 511 exposed to the outside, thereby closing the other side of the main conduit 110 .

Hereinafter, the operation of the manual control valve installation structure of the hot water distributor having the above configuration will be described.

An automatic control valve (S) for heating ON/OFF control is installed in the return pipe (100A), and a manual control valve (400) for controlling the heating water output is installed in the supply pipe (100B) below the return pipe (100B). . At this time, the return pipe (100A) and the supply pipe (100B) are designed to have the same structure, so the operator can screw the automatic control valve (S) and the manual control valve (40) to the valve unit 300 in the same way. can

In detail, the operator attaches the body 410 to which the first cover 411 and the second cover 412 are coupled to the valve part 300, and then attaches the fastening means to the first coupling hole 411c and the second coupling hole 411c. The coupling of the manual control valve 400 to the valve part 300 of the cap tube 100 is made by screwing into the screw groove 300a through the ball 412d.

At this time, the elastic member 420 is spaced apart from the third flow path 313 through the handle 430 as shown in FIG. 7A , and the main pipe line 110 and the valve pipe line 310 are opened. . In this state, when the manager opens the automatic control valve (S) to open the pipe line of the return pipe 100A and controls the temperature, the heating water is discharged from the supply pipe 100B and then goes through each room to the return pipe 100A. Each room is heated through a water-return process.

Meanwhile, the operator may close the main pipe 110 and the lower pipe 210 of the supply pipe 100B for maintenance of the heating system. To this end, the operator holds the grip portion 431 of the handle 430 of the manual control valve 400 and rotates to move the handle 430 to the left as shown in FIG. 7B . At this time, the other end of the handle 430 pushes the contact portion 421 of the elastic member 420 so that the contact portion 421 closes the third flow path 313 as shown in FIG. 7B . Accordingly, the main pipe line 110 and the lower pipe line 210 of the supply pipe 100B are closed, and the operator can perform heating system maintenance work.

Thereafter, when the heating system maintenance work is completed, the operator opens the main pipe 110 and the lower pipe 210 of the supply pipe 100B. To this end, the operator rotates the handle 430 to move it to the right as shown in FIG. 7A . At this time, as the elastic member 420 is restored to its original position due to the nature of the material, the third flow path 313 is opened to open the main pipe line 110 and the lower pipe line 210 of the supply pipe 100B.

As described so far, the manual control valve installation structure of the hot water distributor according to the present invention has the same design of the supply pipe 100B and the return pipe 100A, and the opening and closing action of the manual control valve 400 through screw rotation is designed to make it happen. Accordingly, it is possible to reduce the manufacturing cost of the capillary 100 and the manual control valve 400, and furthermore, it is possible to reduce the construction cost of the hot water distributor and the heating system.

Although the present invention has been described in detail with respect to the embodiments described above, it is obvious to those skilled in the art that various modifications and variations are possible within the scope of the technical spirit of the present invention, and it is natural that such variations and modifications belong to the appended claims.

100: main pipe 100A: return pipe
100B: supply pipe 110: main pipe
200: lower pipe part 200a: reinforcing rib
210: lower pipe 300: valve part
300a: screw groove 310: valve pipe
311: 1st Euro 312: 2nd Euro
313: third flow path 400: control valve
410: body 411: first cover
411a: central hole 411b, 412c: step
411c: first coupling hole 412: second cover
412a: screw hole 412b: seating groove
412d: second coupling hole 420: elastic member
421: close contact 430: handle
431: grip part 500: closing cap
510: central part 511: communication hole
520: coupling portion W: guide wall
H: fastener

Claims (6)

a main pipe forming a main pipe through which heating water is introduced or exchanged from one side;
a lower pipe part that is installed toward the lower side of the main pipe and is branched from the main pipe to form a lower pipe for supplying hot water to each room or returning the hot water circulating in each room;
a valve part formed between the lower pipe line and the main pipe line and including a valve pipe line communicating the lower pipe line and the main pipe line, and formed to be exposed toward the front of the cap pipe; and
It is installed so as to be detachable from the valve part, and includes a control valve provided to open and close the valve conduit,
The control valve is
a body installed to be detachably from the valve unit;
an elastic member installed on the body and installed to face the valve conduit;
It is screwed to the body and includes a handle for closing the valve conduit by pushing the elastic member through screw rotation,
The valve pipe is
a first flow passage formed to communicate in the same direction as the lower pipe passage;
a second flow path for converting the heating water transfer direction of the first flow path toward the front of the cap tube;
Including a third flow path formed between the main pipe and the second flow path and forming a flow path toward the front of the capillary in a direction perpendicular to the main pipe,
The valve conduit does not allow the heating water to flow in a straight line, but is configured so that the flow of the heating water can be switched. Manual control valve installation structure of hot water distributor. According to claim 1,
A screw groove facing the front of the capillary is formed in the valve part,
A coupling hole is formed in the body at a portion corresponding to the screw groove,
A manual control valve installation structure for a hot water distributor, characterized in that a fastening screw capable of being screwed into the screw groove through the coupling hole is provided. 3. The method of claim 2,
The body is
a first cover having a first coupling hole corresponding to the screw groove of the valve part and having a central through hole through both sides in the center;
a second cover coupled to the first cover and having a second coupling hole corresponding to the first coupling hole and having a screw hole having a smaller diameter than the diameter of the central through hole;
It includes a handle screwed to the screw hole to move straight toward the central hole,
The elastic member is installed in the central through hole, the manual control valve installation structure of the hot water distributor, characterized in that it closes the valve conduit while being pushed through the screw rotation of the handle. delete 4. The method according to any one of claims 1 to 3,
The elastic member is a manual control valve installation structure of a hot water distributor, characterized in that configured to open and close the third flow path. 4. The method according to any one of claims 1 to 3,
The control valve is installed in the valve part of the supply pipe, and an automatic control valve for automatically opening and closing the valve pipe of the return pipe is installed in the return pipe.

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