KR20210140873A - An all-in-one valve pipe module of a hot water distributor - Google Patents

Abstract

The present invention relates to a valve-integrated pipe module of a hot water distributor and, more specifically, to a valve-integrated pipe module of a hot water distributor, which includes a lower pipe for water exchange or water supply and a valve pipe perpendicular to each other to omit a separate pipe structure from a main pipe to be integrally injection-molded only with a first mold, thereby increasing manufacturing convenience and reducing manufacturing costs. To this end, provided is a valve-integrated pipe module of a hot water distributor. The valve-integrated pipe module comprises: a body forming a main pipe through one side of which heated water is introduced or exchanged; a lower pipe part installed toward a lower side of the body, and forming a plurality of lower pipes branched from the main pipe to supply hot water to each room or exchange hot water having circulated through each room; a valve part including a valve pipe formed between the lower pipes and the main pipe to communicate the lower pipes with the main pipe; and an opening and closing valve installed to be detachable from the valve part and provided to open and close the valve pipe. The valve part is formed in a direction perpendicular to the lower pipe part. A pipe structure crossing the top and bottom of the main pipe in the longitudinal direction of the main pipe is omitted from the main pipe, and thus the valve-integrated pipe module can be injection-molded only with the first mold.

Description

An all-in-one valve pipe module of a hot water distributor}

The present invention relates to a valve-integrated capillary module of a hot water distributor, and more particularly, to a valve-integrated capillary module of a hot water distributor in which a water supply pipe or a return pipe and a valve pipe are integrally molded to reduce manufacturing costs. .

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 goes 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 in which heating is not required. 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 includes a water supply cap tube module 1 for distributing and supplying the hot water generated in the boiler to each heating zone, and returns the hot water that has dropped in temperature while circulating in each heating zone to send it back to the boiler. It includes a return capillary module (2) and brackets (3,3') for horizontally installing and supporting the capillary modules (1,2) at different positions.

As shown in Fig. 2a, the capillary module (1,2) includes a main body 10 forming a main conduit, and a plurality of water supply units 11 forming a conduit downward from the main conduit of the main body 10, and, A plurality of control valves 12 installed on the upper portion of the main body 10 to correspond to the water supply 11 are included to control the amount of hot water supplied while opening and closing the main pipeline and the pipelines of the water supply unit 11 . At this time, the control valve 12 forms a pipeline in a straight line with the water supply part 11, and as shown in FIG. 2b , the flow control handle 12a, the adapter 12b, and the port 12c at the lower end are coupled to the stem. (12d) and a flow path guide (12e). The flow rate control handle 12a is formed to be exposed at the upper end of the capillary modules 1 and 2, and is provided to adjust the flow rate through rotation. The adapter 12b is coupled to the valve installation hole 13 formed in the capillary modules 1 and 2 to seat the flow rate control handle 12a on the upper portion, and the stem 12d is inserted inside. The stem (12d) has a flow rate control handle (12a) coupled to the upper end, and a semi-circular ball type port (12c) is integrally formed at the lower end. The flow guide 12e is formed in a cylindrical shape through which the inside is penetrated, and the degree of opening and closing is determined by the port 12c formed at the lower end of the stem 12d. The fluid introduced into the capillary modules 1 and 2 having such a configuration has a maximum flow rate through the flow guide 12e when the port 12c is lifted to the top and the upper end of the flow guide 12e is maximally opened. However, when the port 12c descends to gradually seal the upper end of the flow guide 12e, the flow rate flowing into the flow guide 12e is gradually reduced.

Accordingly, the hot water distributor can control the temperature of each room while controlling the hot water flow rate.

However, the conventional hot water distributor has the following problems. The capillary modules 1 and 2 of the hot water distributor require a separate flow guide 12e to configure the hot water in/out flow path, so there is a problem in that it is difficult to perform injection molding with the primary mold at one time. That is, the capillary modules 1 and 2 of the hot water distributor require injection molding of the main body 10 constituting the main pipe and the flow guide 12e, and then coupling them together. ,2) It is not easy to manufacture, and a secondary mold and injection molding are required, which causes a problem in that the manufacturing cost is increased. Furthermore, there is a problem in that the increase in the manufacturing cost of the hot water distributor increases the heating system construction cost.

Republic of Korea Publication No. 10-2017-0037803

The present invention has been devised to solve the above problems, and an object of the present invention is to simplify the pipe configuration by integrally designing a lower pipe and a valve pipe through which heating water flows in or out, so that injection molding can be performed once with only the primary mold. It is intended to provide a valve-integrated capillary module of a hot water distributor so that manufacturing costs can be reduced by making this happen.

The present invention, in order to achieve the above object, a main body forming a main conduit through which heating water is introduced or exchanged from one side; a lower pipe part installed toward the lower side of the main body and branching in plurality from the main pipe to form a lower pipe for supplying hot water to each room or returning hot water circulating in each room; a valve unit formed between the lower conduit and the main conduit and including a valve conduit for communicating the lower conduit with the main conduit; and an opening/closing valve installed so as to be detachably from the valve part and provided to open and close the valve pipe, wherein the valve part is formed in a direction perpendicular to the lower pipe part, and the main pipe is on the main pipe. Provided is a valve-integrated capillary module of a hot water distributor, characterized in that injection molding can be performed only with the primary mold by omitting the pipe structure crossing the top and bottom of the main pipe in the longitudinal direction.

In addition, the valve pipe may include: a first flow path formed to pass in the same direction as the lower pipe; a second flow path for converting the heating water transfer direction of the first flow path toward the front of the main body; It is preferable to include a third flow path formed between the main pipe path and the second flow path, and forming a flow path toward the front of the body in a direction perpendicular to the main pipe path.

In this case, it is preferable that the opening/closing valve is configured to automatically open and close the third flow path.

In this case, it is preferable that a guide wall for guiding the heating water from the first flow path to the second flow path is formed in the first flow path.

The valve valve integrated capillary module of the hot water distributor according to the present invention has the following effects.

First, the capillary module of the hot water distributor integrally consists of the lower pipe and the valve pipe, so that the cap module itself can be injection molded with only the primary mold. That is, the capillary module of the hot water distributor constitutes the pipeline, integrally configuring the pipeline with the body itself, and does not constitute a separate structure on the main pipeline of the body. , the present invention is that injection molding can be made only with the primary mold. Accordingly, the cap tube module of the hot water distributor can reduce the mold manufacturing cost, there is an effect that can reduce the manufacturing cost of the cap tube module. Furthermore, there is an effect of reducing the heating system construction cost by reducing the manufacturing cost of the cap tube module.

Second, the capillary module of the hot water distributor configures the valve pipe in a direction perpendicular to the lower pipe, that is, on the front side of the main body, so that the length of the pipe through which the hot water moves can be minimized, thereby reducing the hot water circulation time and increasing the efficiency. have.

1 is a view showing a hot water distributor according to the prior art from the front.
Figure 2a is a perspective view showing the cap tube module of the hot water distributor according to the prior art.
Figure 2b is an exploded perspective view showing the cap tube module of the hot water distributor according to the prior art.
3 is a perspective view showing a hot water distributor in which a valve-integrated capillary module of the hot water distributor is installed according to a preferred embodiment of the present invention.
4 is a perspective view showing a valve-integrated capillary module of a hot water distributor according to a preferred embodiment of the present invention.
5 is a front view showing a main part of a valve-integrated capillary module of a hot water distributor according to a preferred embodiment of the present invention.
6A is a cross-sectional view taken along line II of FIG. 5 .
FIG. 6B is a view showing a line II-II of FIG. 6A.
Figure 6c is a bottom view showing the bottom of Figure 4;

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 can 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 valve-integrated capillary module (hereinafter referred to as a 'capillary module') 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 6c.

The capillary module is provided for heating water supply or heating water return, and has a technical feature formed integrally through injection molding. Accordingly, it is possible to reduce the manufacturing cost of the hot water distributor, and furthermore, it is possible to reduce the heating system construction cost.

The capillary module 100 is composed of a water supply capillary module 100A and a return capillary module 100B as shown in FIG. 3 , and the capillary module 100 is installed at the upper and lower parts through the bracket (B), respectively. . The water supply capillary module 100A and the return capillary module 100B may be provided in different configurations to the hot water distributor as shown in FIG. 3, and although not shown, the water supply capillary module 100A and the return capillary module 100B) may be provided in the hot water distributor in the same configuration as each other. The capillary module 100 in the preferred embodiment will be described by taking the return capillary module 100B as an example.

As shown in FIGS. 3 to 5 , the capillary module 100 includes a main body 110 , a lower pipe part 120 , a valve part 130 , an opening/closing valve 140 , and a closing cap 150 . include

The body 110 forms a main pipe 111 through which heating water is exchanged, and is provided as a circular pipe. Male screws for fixing to the bracket (B) are formed on both sides of the main body (110). Both ends of the body 110 are fixed to the bracket through the through-hole of the bracket (B) through screw coupling with the closing cap 150 to be described later. The body 110 may be any material that can be injection molded through a mold.

The lower pipe part 120 is a pipe through which the heating water circulated through the floor of the room flows, and is provided in the lower part of the main body 100 . The lower pipe part 120 forms a lower pipe line 121 branched from the main pipe line 110, and the lower pipe line 121 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 120 so that a pipe for returning heating water from each room can be screwed. That is, since the lower pipe part 120 and the valve part 130 are configured to be perpendicular to each other, there is no need to construct a separate pipe structure crossing the top and bottom of the main pipe line 110 , the main pipe line 110 . As shown in FIGS. 6A and 6B , it has a hollow shape. As such, in the present invention, since there is no separate structure in a straight line in the main pipe line 110, it can be separated without interference when separating the molded product, the capillary module 100 in the longitudinal direction, after injection molding. If a separate pipe structure (conventional flow guide) is provided in the center of the main pipe 111 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 main body 110 On the other hand, the process of mutually coupling the flow guide and the flow guide may cause problems, etc., but in the present invention, injection molding can be easily performed only with the primary mold by vertically configuring the valve part 130 and the lower pipe part 120 . there will be This configuration has the advantage of lowering the convenience of manufacturing the capillary module 100 and the manufacturing cost. On the other hand, it is preferable that the reinforcing ribs 120a are formed in the lower pipe part 120 as shown in FIG. 6c. A metal connecting means is coupled to the lower pipe part 120 , and the reinforcing rib 120a increases the durability of the lower pipe part 120 made of a resin material, thereby damaging the lower pipe part 120 in the process of connecting the metal connecting means. This is to prevent this from happening. The reinforcing rib (120a) is preferably in the form of a cross that crosses the lower conduit (121).

The valve unit 130 provides a conduit for controlling the inflow of the heating water returned through the lower conduit 121 into the main conduit 110 . That is, the valve unit 130 is configured such that the on/off valve 140 to be described later opens and closes the valve conduit 131 to turn on/off heating. As shown in FIGS. 3 and 4 , the valve unit 130 is installed in plurality on the front surface of the body 110 when the hot water distributor is viewed from the front. The valve unit 130 having such a configuration is formed perpendicular to the lower pipe unit 120 . The valve unit 130 is preferably provided with a screw groove so that the opening/closing valve 140 can be detached. The valve conduit 131 of the valve unit 130 communicates with the main conduit 111 and the lower conduit 121, and as shown in FIG. 6a , a first channel 131a and a second channel 131b, and a third flow path 131c. As described above, the valve part 130 is vertically configured with respect to the lower pipe part 120 in order to increase the convenience and quality of injection molding of the cap tube module 100 and reduce the manufacturing cost of the cap tube module 100, which is shown in Fig. 6a. can be understood through

The first flow path 131a of the valve conduit 131 forms a flow path communicating with the lower conduit 121 as shown in FIG. 6A , and the heating water introduced through the lower conduit 121 is transferred to the second flow path 131b. Euro to guide you to The first flow path 131a faces downward of the main body 110 and is formed in a straight line with the lower pipe line 121 . The first flow path 131a forms a guide wall W for guiding the heating water to the second flow path 131b. The guide wall W is preferably provided at a right angle toward the second flow path 131b. The second flow path 131b is a flow path for changing the direction of the heating water flowing in from the first flow path 131a toward the front of the hot water distributor. The third flow path 131c communicates with the main pipe path 111 , and is a flow path for discharging the heating water of the second flow path 131b to the main pipe path 111 . The third flow path 131c is formed in the same direction as the second flow path 131b, but the flow direction of the heating water is opposite. The valve conduit 131 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. It can be seen that the configuration is perpendicular to . This configuration can promote the omission of the pipe structure of the main pipe line 111, and increase the convenience of manufacturing a mold for injection molding of the parent pipe module 100, so that the cap pipe module 100 can be manufactured with only the primary mold. This has the advantage of reducing the manufacturing cost of the capillary module 100 .

The opening/closing valve 140 controls the return of heating water to the main pipe 111 by opening and closing the valve pipe 131 to turn on/off heating. The opening/closing valve 140 is installed to open and close the third flow path 131c of the valve pipe path 131 , and is installed to be detachably attached to the valve unit 130 . The opening/closing valve 140 is preferably provided to automatically open and close the third flow path 131c, and may be provided as a solenoid valve. Of course, the on/off valve 140 is not limited to a solenoid valve.

The closing cap 150 serves to couple the capillary module 100 to the bracket. As shown in FIG. 3 , the closing cap 150 has a central portion 151 having a central through hole 151a communicating with the main conduit 111 of the main body 110 through both sides thereof, and the outer circumference of the central portion 151 . Accordingly, the coupling portion 152 is formed. A female screw is formed on the inner circumferential surface of the coupling part 152 to be screw-coupled to both male screws of the main body 110 . That is, the inner diameter of the coupling portion 152 corresponds to the outer diameter of the body 110 . The central portion 151 is configured to be inserted into the main conduit 111 of the main body 110 and forms a central through hole 151a for recovering heating water from the main body 110 . As both sides of the central through hole 151a are formed through, the heating water may be recovered from the main pipe 111 of the body 110 . The outer diameter of the central portion 151 corresponds to the inner diameter of the main conduit 111 , and a female screw is formed on the inner circumferential surface of the central through hole 151a. On the other hand, one side of the main conduit 111 of the main body 110 is a passage through which heating water is recovered, but the other side of the main conduit 111 must be closed. To this end, among the closing caps 150 coupled to the other side of the main body 110, a stopper (not shown) capable of closing the central through hole 151a is coupled. The outer diameter of the stopper corresponds to the inner diameter of the central through hole (151a), the outer peripheral surface of the stopper is formed with a male screw. That is, the inner peripheral surface of the central through-hole (151a) is formed of a female screw, the stopper can be screwed to the exposed central through-hole (151a) to close the other side of the main conduit (111).

Hereinafter, we will look at the process of heating and exporting water through the capillary module having the above configuration.

The manager adjusts the temperature of the heating water by manipulating a temperature controller (control unit; not shown) in a state in which the water supply pipe path of the water supply cap pipe module 100A is opened, and opens the valve pipe line 131 in the area requiring heating to the main The conduit 111 and the lower conduit 121 are communicated. The valve conduit 131 is opened as the opening/closing valve 140 automatically opens the third flow path 131c by the manager's operation of the temperature controller.

Thereafter, the heated heating water is discharged through the water supply pipe and circulates in the heating zone, and then is returned to the main pipe 111 through the lower pipe 121 to provide heating. On the other hand, in order to turn off the heating, the manager operates the thermostat to cause the on-off valve 140 to close the third flow path 131c, so that the return of the heating water is blocked and the heating is turned off. As this series of process is repeated, heating ON/OFF is performed.

As described so far, the valve-integrated capillary module of the hot water distributor according to the present invention comprises the valve pipe line 131 and the lower pipe line 121 perpendicular to each other in the longitudinal direction of the main pipe line 111 on the main pipe line 111. A plurality of conduit structures may be omitted. Accordingly, in the present invention, since there is no interference on the main pipe line 111 after injection molding for manufacturing the capillary module, separation of the molded product can be performed without any problem, so that the capillary module in which all pipelines are formed can be made with only the primary mold. have. This can reduce the manufacturing cost of the cap tube module, and further reduce the heating construction cost.

Although the present invention has been described in detail with respect to the described embodiments, it is apparent 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: capillary module 100A: water supply capillary module
100B: return capillary module 110: body
111: main pipe 120: lower pipe part
121: lower pipe 130: valve part
131: valve pipe 131a: first flow path
131b : 2nd Euro 131c : 3rd Euro
140: on/off valve 150: closing cap
151: central part 151a: central hole
152: coupling part B: bracket
W: guide wall

Claims (4)

a body forming a main conduit 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 body 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 unit formed between the lower conduit and the main conduit and including a valve conduit for communicating the lower conduit with the main conduit; and
It is installed so as to be detachable from the valve part, and includes an on-off valve provided to open and close the valve conduit,
The valve part is formed in a direction perpendicular to the lower pipe part, so that injection molding can be made only with the primary mold by omitting the pipe structure that crosses the top and bottom of the main pipe in the longitudinal direction of the main pipe on the main pipe. A valve-integrated capillary module of a hot water distributor, characterized in that According to claim 1,
The valve pipe is
a first flow path formed to pass in the same direction as the lower pipe;
a second flow path for converting the heating water transfer direction of the first flow path toward the front of the main body;
and a third flow path formed between the main pipe line and the second flow path and forming a flow path toward the front of the main body in a direction perpendicular to the main pipe line. 3. The method of claim 2,
The valve-integrated capillary module of the hot water distributor, characterized in that the opening/closing valve is configured to automatically open and close the third flow path. 4. The method of claim 2 or 3,
The first flow path has a guide wall for guiding the heating water from the first flow path vertically to the second flow path.

Images