KR102273037B1 - Smart hybrid distributor with easy nipple connection recognition - Google Patents

Abstract

The present invention relates to a smart hybrid distributor which can sense the pressure and temperature of hot water during heating to adjust flow automatically, and can recognize the state of a pipe being combined by a nipple easily. More specifically, disclosed is a smart hybrid distributor with easy nipple connection recognition, which has a smart sensor installed on an automatic flow adjustment valve installed on a water recovery pipe of hot water supplied to each house to sense and measure the pressure and temperature of the hot water, can automatically adjust flow using the measured pressure and temperature of the hot water and the current temperature and set temperature of each heating controller, and can prevent defects caused by water leakage and time elapse that can be generated when a pipe is combined without being inserted completely as the state of the pipe being combined while being inserted completely into a nipple can be recognized easily when the pipe is combined with the automatic flow adjustment valve or a manual flow adjustment valve installed on a supply pipe of hot water using the nipple.

Description

Smart hybrid distributor with easy nipple connection recognition

The present invention relates to a smart hybrid distributor capable of automatically adjusting the flow rate by sensing the pressure and temperature of hot water during heating, and easily recognizing a state in which a pipe is coupled by a nipple. A smart sensor is installed in the flow control valve installed in the branch pipe of the hot water to which water is supplied or returned to sense and measure the pressure and temperature of the hot water, and the measured pressure and temperature of the hot water and the current temperature of each heating room controller The flow rate can be automatically adjusted using a set temperature, and when the pipe is coupled to the flow control valve using a nipple, the pipe is completely inserted into the nipple and it is easy to recognize the coupled state, so that the pipe is completely inserted It is a technical field related to a smart hybrid dispenser that can easily recognize nipple coupling that can prevent leaks that may occur when they are combined without being coupled with time and can prevent lapse defects in advance.

The heating method is divided into individual heating method, central heating method, and district heating method according to the production method of the heat source. The individual heating method is heating by individual boilers installed for each household (household), and the central heating method is for each complex. The heat source produced in each central machine room is supplied to each household directly or through a heat exchanger in the machine room to provide heating. In the district heating method, the heat source produced collectively by production facilities such as a combined heat and power plant of a certain area or a certain scale is used for heating. It is a method of heating by supplying apartment complexes or large buildings in a certain area.

In the heating methods as described above, a distributor for distributing heating water is installed in each heating room requiring heating in common, and the distributor receives heating water through a heating water supply pipe and supplies heating water to each heating room. The heating water supplied to the heating room is configured to be cooled and discharged to the outside through a heating water return pipe after transferring heat energy through a heating pipe installed in each heating room.

At this time, a flow rate control valve corresponding to the number of the heating rooms is installed in the distributor so that the flow rate of heating water is controlled and supplied to each heating room, and the flow control valve is configured to control the size of each heating room or the external environment. The heating water supply flow rate for heating is differently supplied to each heating room according to the conditions, so that the same temperature rises at a certain time.

According to the control method, these flow control valves are classified into three types: ON/OFF type, constant flow type, and proportional control method. When the temperature of the heating room reaches the temperature set by the user, the valve is blocked to cut off the supply of heating water, and when the temperature of the heating room falls below the temperature set by the user, the valve is closed. It is open to supply heating water.

In the constant flow method, when a valve is installed in a heating water return pipe through which heating water is returned, heating water does not flow beyond the flow rate set in the valve itself, and heating water is supplied to a plurality of heating rooms from one heating water supply source Because the length of the pipe in each heating room is different, the time for the temperature of each heating room to reach the set temperature is different. In order to solve this heating imbalance, a flow control valve is installed on the pipe connected to each heating room. By installing, the time to reach the set temperature of each heating room is made uniform.

This constant flow method is known to have advantages of reducing the total length of the heating pipe, reducing the number of distributors, and resolving the heating imbalance, and was used in the heating system.

However, in the constant flow method, the construction company sets the flow rate at the time of construction according to the length of the pipe and the diameter of the pipe, and once the flow rate is set, it is impossible for the user to change the flow rate arbitrarily. If the length is changed, the problem of heating imbalance may occur again.

In addition, in the constant flow method, the amount of heat required in each heating room during heating is not determined only by the length of the pipe, but the location of each heating room (whether it is a sunny room or not) and the degree of insulation of each heating room. Depending on the conditions, there is a difference in the amount of heat required for each heating room for equalization of the actual heating, and this is manual, that is, in the case of the constant flow method in which the flow rate is adjusted during construction, the flow rate is adjusted according to the actual condition of each heating room. There is a problem that this cannot be done.

On the other hand, a proportional control method was developed to solve the problems of the constant flow method as described above. In the proportional control method, a flow control valve is installed in the distributor on the side where the heating water supplied from the heating water supply source passes through each heating room and then is returned. installed to adjust the flow rate of heating water to create a comfortable indoor environment according to the temperature set in each heating room.

However, the conventional proportional control type flow control valve controls the supply flow rate of heating water by receiving flow data feedback from the flow sensor and adjusting opening and closing, but there is a problem in that the flow sensor is contaminated because there are many foreign substances in the heating water.

In addition, when the flow sensor is not used, the temperature sensor measures the return temperature of the heating water, and the measured return temperature is fed back to the target (set) temperature and the current temperature until the target temperature is reached. PID (Proportional-plus-Integrate-plus-Derivative) control, which calculates the deviation from and gives a control amount proportional to the deviation value, was used. That is, this method calculates the deviation between the target (set) temperature and the current temperature, adjusts the opening/closing amount of the flow control valve in proportion to the deviation value, and then measures the change in the current return temperature again to measure the opening/closing amount of the flow control valve It is a method to control the flow rate by repeatedly adjusting the opening and closing of the flow control valve until the target (set) temperature is reached.

On the other hand, when the distributors according to the heating method as described above supply or exchange hot water to each heating room, they are connected to the pipes connected to the respective heating rooms, that is, the hot water supply pipe and the hot water return pipe, and the hot water supplied therebetween. And the flow rate control valve described above to control the flow rate of the returned hot water is installed.

That is, the hot water supply pipe and the hot water return pipe connected to each of the heating rooms are connected to the flow control valve and installed. At this time, the flow control valve not only facilitates the installation of the hot water supply pipe and the hot water return pipe, but also prevents leakage. Nipple is used so that it can be firmly coupled.

However, the nipple used in the conventional flow control valve is filled with epoxy in the insertion groove formed in the nipple into which the hot water supply pipe and the hot water return pipe are inserted in order to prevent leakage and solid coupling of the hot water supply pipe and the hot water return pipe. As time passes, there is a problem that maintenance is required because defects such as leakage occur due to deterioration of durability due to corrosion of the epoxy.

In addition, when the hot water supply pipe and the hot water return pipe are coupled to the flow control valve by a nipple, when the operator is fixed to the flow control valve in a state that is not completely inserted into the insertion groove formed in the nipple, leakage and time elapse There is a problem that a transient defect may occur as a result of this.

Republic of Korea Patent Registration No. 10-0341920 (June 12, 2002)

The present invention is a technology devised to solve the problems according to the above-mentioned prior art, and is filled when the hot water supply pipe and the hot water return pipe are combined with the flow control valve used in the proportional control method using PDI control among the conventional heating methods. As the epoxy passes over time, not only leaks and defects occur due to the corrosion of the epoxy, but also the hot water supply pipe and the hot water return pipe are completely inserted into the nipple of the flow control valve between the hot water supply pipe and the hot water return pipe. a defect has occurred;

As a solution to this, instead of filling the epoxy between the coupling part of the flow control valve and the branch nipple coupled to the coupling part, the first O-ring and the second packing are installed to facilitate installation and effectively prevent leakage. Then, the identification tag is installed in the insertion groove formed in the branch nipple after passing through the display hole on the outer periphery of the branch nipple so that the identification tag is recognized through the display hole by the branch pipe or inserted into the insertion groove By using a pin clip that is completely inserted into the insertion groove when the branch pipe is fully inserted, it is possible to more easily check the state in which the branch pipe is completely inserted and coupled, so that leakage and lapse defects due to the passage of time are delayed. Its main purpose is to provide through a smart hybrid distributor that is easy to recognize nipple coupling that can be prevented.

The present invention is a hot water distributor that receives heating water from a heating water supply source in order to realize the above object, one side is connected to the hot water distributor, and the other side is connected to the hot water distributor through each heating room It is installed between the engine and the hot water distributor and the branch pipe, and has a smart sensor for measuring the pressure or temperature and pressure and temperature of hot water, and the opening and closing amount is adjusted to measure the flow rate of the heating water supplied to each heating room. It is configured to include a flow rate control valve for controlling, the flow rate control valve is a coupling part formed to protrude on the other side, and one side is coupled to the coupling part, and a branch nipple into which the hot water supply pipe or the hot water return pipe is inserted and fixed; Presents a smart hybrid dispenser that facilitates recognition of nipple coupling, characterized in that it comprises a first O-ring installed between the coupling part and one end of the branch nipple.

In addition, the flow control valve of the present invention is characterized in that it is configured to include a second packing installed between the other end of the coupling portion and the branch nipple.

In addition, the branch nipple of the present invention is formed on one side, and is formed to extend to the other side of the inner inlet and the inner inlet, which is inserted into and coupled to the other side of the coupling portion of the flow control valve, and is formed to have a larger diameter than the inner inlet. A press-fitting part extending to the other side of the nut coupling part and the inner fitting part to be formed, extending to have the same inner diameter as the inner fitting part, and forming an insertion groove into which one side of the branch pipe is inserted between the nut coupling part And installed on the outer periphery of the press-fitting part, the press-fit ring installed so as to be located outside the outer periphery of one side of the branch pipe and screwed to the outer periphery of the nut coupling part, the press-fit as it is screwed to the outer periphery of the nut coupling part It is characterized in that it is configured to include a fixing nut for pressing the ring.

In addition, the branch nipple of the present invention is formed through the outer periphery of one side of the nut coupling part, is inserted into the insertion groove and the display hole which is formed through to be positioned at one end of the insertion groove, and is inserted into the insertion groove It is characterized in that it is configured to include an identification tag that is moved in one direction by the branch pipe.

In addition, the display hole of the present invention is characterized in that it is formed to be inclined in one direction toward the upper part, and when the identification tag is moved in one direction by the branch pipe, the identification tag is inserted by one end of the branch pipe It is characterized in that, the identification tag is characterized in that the color is distinguished from the color of the nut coupling part.

In addition, the branch nipple of the present invention is installed with one side inserted into the insertion groove, one end of which is vertically bent in the inward direction, and the other end of the branch nipple is configured to include a pin clip bent so as to be inclined in the outward direction. do.

In addition, the pin clip of the present invention is characterized in that the straight length from the edge of the bent one end to the other end is the same as the length of the insertion groove, and the length of the bent one end is the same as the height of the insertion groove. characterized by being

The smart hybrid distributor, which is easy to recognize nipple coupling according to the present invention presented as described above, is when one side of the branch nipple coupled to the coupling part and the coupling part of the flow control valve is coupled, one end of the branch nipple and the flow rate control The first O-ring is installed between the inner side of the coupling part of the valve, and the second packing is installed between the other end of the coupling part of the flow control valve and the outer periphery of the branch nipple to improve watertightness without using the conventional epoxy filling. Thus, it is possible to obtain the effect of effectively preventing leakage.

In addition, the present invention is formed by penetrating the display hole on the outer periphery of the branch nipple, and after installing the identification tag in the insertion groove into which the branch pipe is inserted, the identification tag is visually confirmed in the display hole as the branch pipe is inserted. By doing so, it is easier to check the fully inserted state of the branch pipe to easily recognize the coupled state, and accordingly, the effect of efficiently preventing water leakage by stably forming watertightness by the strong coupling of the branch pipe can get

In addition, in the present invention, when the branch pipe is completely inserted using a pin clip having one side inserted into the insertion groove of the branch nipple and the other side is bent in the outward direction of the branch nipple, the pin clip is completely inserted into the insertion groove. By inserting inside, it is easy to check whether the fixing nut of the branch nipple is fully coupled, so that it is easy to recognize the complete insertion of the branch pipe, and thus water tightness is stably formed by the strong coupling of the branch pipe. It is possible to obtain the effect of effectively preventing leakage.

1 is a schematic diagram showing a dispenser according to a preferred embodiment of the present invention.
Figure 2 is a partial enlarged perspective view showing a distributor according to a preferred embodiment of the present invention.
Figure 3 is a partially exploded perspective view showing a distributor according to a preferred embodiment of the present invention.
4 is a partial cross-sectional view showing a dispenser according to a preferred embodiment of the present invention.
Figure 5 is a partial cross-sectional view of the dispenser showing the movement of the dog tag according to the preferred embodiment of the present invention.
Figure 6 is a partial enlarged perspective view showing a branch nipple according to a preferred embodiment of the present invention.
Figure 7 is a partial enlarged perspective view of another angle showing a branch nipple according to a preferred embodiment of the present invention.
Figure 8 is a partially exploded perspective view showing a distributor according to another embodiment of the present invention.
9 is a partial cross-sectional view showing a dispenser according to another embodiment of the present invention.
Figure 10 is a partial cross-sectional view of the distributor showing the movement of the pin clip according to another embodiment of the present invention.
11 is a perspective view showing a pin clip according to another embodiment of the present invention.

The present invention relates to a smart hybrid distributor capable of automatically adjusting the flow rate by sensing the pressure and temperature of hot water during heating, and easy to recognize the state in which the pipe, that is, the branch pipe 200 is coupled by the branch nipple 330 As that, to explain in more detail, the smart sensor 310 is installed in the flow control valve 300 installed in the branch pipe 200 to which heating water is supplied or returned for each household, and the pressure and temperature of the hot water are sensed and measured. , the flow rate can be automatically adjusted using the measured pressure and temperature of hot water and the current temperature and set temperature of each heating room controller, and the branch pipe using the branch nipple 330 to the flow control valve 300 . When coupling 200, the branch pipe 200 is completely inserted into the branch nipple 330, so it is easy to recognize the coupled state, which may occur when the branch pipe 200 is not completely inserted and combined. It is a technology related to a smart hybrid distributor with easy nipple connection recognition that can prevent leaks and transient defects over time.

The configuration for achieving the present invention as described above is a hot water distributor 100 receiving heating water from the heating water supply source 10; and one side is connected to the hot water distributor 100, and the other side is each heating room (R) ) through a branch pipe 200 connected to the hot water distributor 100; and a smart sensor installed between the hot water distributor 100 and the branch pipe 200 and measuring the pressure and temperature of hot water ( 310), and the opening and closing amount is adjusted to control the flow rate of the heating water supplied to each of the heating rooms (R). a coupling part 320 protruding from the coupling part 320, one side coupled to the coupling part 320, and a branch nipple 330 into which the hot water supply pipe 210 or the hot water return pipe 220 is inserted and fixed; and a first O-ring 340 installed between the coupling part 320 and one end of the branch nipple 330 .

In addition, the flow control valve 300 of the present invention is configured to include a second packing 350 installed between the other end of the coupling part 320 and the branch nipple 330 . .

In addition, the branch nipple 330 of the present invention is formed on one side, and is inserted into the other side of the coupling part 320 of the flow control valve 300 and is coupled to the inner inlet 332; and the inner inlet 332 of Doedoe extending to the other side, the nut coupling portion 333 is formed to extend to form a larger diameter than the inner inlet portion 332; and the inner inlet portion 332 is formed to extend to the other side, the same as the inner inlet (332) A press-fitting part 334 extending to form an inner diameter and forming an insertion groove 334a into which one side of the branch pipe 200 is inserted between the nut coupling part 333 and the press-fitting part 334; Doedoe installed on the outer periphery of the press-fit ring 336 is installed so as to be located outside the outer periphery of one side of the branch pipe (200); and a fixing nut 338 which is screwed to the outer periphery of the nut coupling part 333 and presses the press-fit ring 336 as it is screwed to the outer periphery of the nut coupling part 333. characterized by being

In addition, the branch nipple 330 of the present invention is penetrating through the outer periphery of one side of the nut coupling part 333, and a display hole 335 that is formed through to be positioned at one end of the insertion groove 334a; and It is characterized in that it is configured to include; is installed in the insertion groove (334a), the identification tag (331) moved in one direction by the branch pipe (200) inserted into the insertion groove (334a).

In addition, the display hole 335 of the present invention is characterized in that it is formed to be inclined in one direction toward the upper part, and when the identification tag 331 is moved in one direction by the branch pipe 200, the branch pipe ( 200) is characterized in that the identification tag 331 is inserted by the one end, the identification tag 331 is characterized in that the color is distinguished from the color of the nut coupling part (333).

In addition, the branch nipple 330 of the present invention is installed with one side inserted into the insertion groove 334a, one end of which is vertically bent in the inward direction, and the other end is bent so as to be inclined outwardly in a pin clip 337 );

In addition, the pin clip 337 of the present invention is characterized in that the straight length (L1) of the other end from the edge by the bent one end is the same as the length (H1) of the insertion groove (334a), and the bent one side It is characterized in that the length (L2) of the distal end is formed equal to the height (H2) of the insertion groove (334a).

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 9 showing embodiments of the present invention.

First, schematically explaining the smart hybrid distributor of the present invention, the smart hybrid distributor with easy nipple coupling recognition of the present invention is installed for each generation so that hot water can be supplied from the heating water supply source 10 that produces hot water.

Specifically, the smart hybrid distributor, which is easy to recognize the nipple coupling of the present invention, is connected to the hot water distributor 100 receiving heating water from the heating water supply source 10 and one side of the hot water distributor 100, and the other side is each It passes through the heating room (R) and is installed between the branch pipe 200 connected to the hot water distributor 100 and the hot water distributor 100 and the branch pipe 200, and measures the pressure and temperature of hot water. It has a smart sensor 310 and is configured to include a flow control valve 300 for controlling the flow rate of the heating water supplied to each heating room (R) by adjusting the opening and closing amount.

The hot water distributor 100 recovers the heating water that has passed through the supply main 110 receiving hot water, ie, heating water, from the heating water supply source 10, and each heating room R, and the heating water supply source 10 ) is configured to include a water exchange main 120 to return the water.

The branch pipe 200 has a plurality of hot water supply pipes 210 having one side connected to the outer periphery of the supply main pipe 110 and the other side installed in each heating room R, and one side of each heating room. (R) is configured to include a plurality of hot water return pipe 220 that is respectively connected to the other side of the plurality of hot water supply pipe 210 passed through.

At this time, the flow control valve 300 may be installed between the supply main 110 and the hot water supply pipe 210 or between the return main 120 and the hot water return pipe 220, and each Controlling the flow rate of the waterproofing water supplied to the heating room (R), and equipped with a smart sensor 310 for measuring the pressure and temperature of the heating water, while the opening and closing amount is automatically adjusted to each heating room (R) Controls the flow rate of the supplied heating water.

The heating water supply source 10 means a production facility such as a boiler of an individual heating method, a central machine room of a central heating method, or a cogeneration plant of a certain area or a certain scale of a district heating method, and in the present invention, in order to make it easier to understand An individual heating type boiler will be described as an example, and it will be apparent that other sources may be employed without departing from the scope of the present invention without being limited to the boiler.

The supply main 110 is connected to the heating water supply source 10 and a main supply pipe (not shown) to receive heating water, that is, hot water, and each heating room ( R) so that hot water can be supplied.

One side of the hot water supply pipe 210 is connected to the other side of the supply pipe 110, that is, the other side of the flow control valve 300 as described above, and the other side is a heating pipe (not shown) installed in the heating room (R). It is installed and connected to the hot water return pipe 220 to be described in detail later, but in the present invention, the heating pipe is extended to the hot water supply pipe 210 to be installed up to the heating room (R).

The hot water return pipe 220 has one side connected to the other side of the hot water supply pipe 210, and the other side is connected to a return main pipe 120 to be described in detail later, extending to each heating room (R). It is connected to the hot water supply pipe 210 to recover the heat-exchanged heating water passing through each heating room (R) so that it can be returned.

The return main pipe 120 is connected to the outer periphery of the other side of the hot water return pipe 220 so that the heating water that has passed through each heating room (R) is recovered and returned to the heating water supply source (10).

The flow control valve 300 is installed between the hot water supply pipe 210 and the supply main pipe 110 or between the hot water return pipe 220 and the return main pipe 120, when described in more detail. , The supply main 110 is configured to include a sub-pipe (not shown) integrally protruding from the outer periphery, and the flow control valve 300 is installed so that one side communicates with the sub-division of the supply main 110 And, by being installed so that the hot water supply pipe 210 communicates with the other side, it is installed between the hot water supply pipe 210 and the supply main 110 or the hot water return pipe 220 and the return main 120 .

In addition, the flow control valve 300 is configured to include a smart sensor 310 that measures the pressure and temperature of the returned heating water, the pressure and temperature of the heating water supplied or returned by the smart sensor 310 . It automatically opens and closes according to the preset control setting through the current and set temperature measured and set by the controller of the heating room (R) and adjusts the flow rate of the supplied or returned heating water. As a result, each heating room ( Control the flow rate of heating water supplied to R).

That is, when the controller of the heating room R is operated by an operator or household user, the flow control valve 300 is controlled by a control setting preset in a controller connected to the controller, and the flow rate of the supplied or returned heating water is to be adjusted automatically. At this time, since the preset control setting may use any control setting of a heating system used in the prior art, a detailed description will be omitted, and the controller is a smart hybrid that is easy to recognize the inside of the regulator or the nipple coupling of the present invention It can be installed adjacent to the distributor.

In addition, the flow control valve 300 is installed on one side of the hot water return pipe 220, the other side is provided with a driver (not shown), and opens and closes by the actuator as the actuator is controlled by the controller. The amount is adjusted to adjust the flow rate of the heating water supplied to each heating room (R).

The controller is installed in each heating room (R) to determine whether to heat, each heating room (R) measures the current temperature, and allows the user to set the set temperature, The current temperature and the set temperature of the corresponding heating room (R) are transmitted so that the flow rate of the heating water is controlled by the flow control valve 300 .

The controller is connected to a plurality of regulators installed in each heating room (R) to receive information on whether heating is performed or stopped in each heating room (R), and a current temperature and a set temperature, and a plurality of flow control valves (300) is connected to the smart sensor 310, which will be described in detail later, to control the actuator by receiving the supplied or returned heating water, that is, the return pressure and temperature of hot water every predetermined time, whether heating, current temperature, setting By using the temperature and the return temperature of the hot water, the flow rate of the hot water supplied to each heating room (R) is controlled so that it can be supplied.

In connection with the above, the flow rate control valve 300 installs a branch nipple 330 on the other side so that the hot water supply pipe 210 and the hot water return pipe 220 are connected to the other side, so that the hot water supply pipe 210 and It not only facilitates the connection of the hot water return pipe 220, but also prevents leakage of water.

Specifically, the flow control valve 300 has a coupling part 320 protruding from the other side, and one side is coupled to the other side of the coupling part 320, and the hot water supply pipe 210 or the hot water return pipe ( It is configured to include a branch nipple 330 into which 220 is inserted and fixed, and a first O-ring 340 installed between the coupling part 320 and one end of the branch nipple 330 .

At this time, the flow control valve 300 is installed in an installation hole (not shown) formed by penetrating through the outer periphery of the coupling part 320 , and the installation hole, the lower part protruding into the inside of the coupling part 320 . It is configured to further include a smart sensor 310 that is installed so as to automatically adjust the flow rate of heating water.

The installation hole is formed to penetrate through the outer periphery of the coupling part 320, and it is preferable that the outer periphery upper part, that is, formed so that the operator can be located in the front during operation, which is the maintenance of the smart sensor 310 and to realize the effect of facilitating installation.

As mentioned above, the smart sensor 310 measures the pressure and temperature of the supplied or returned heating water, measured and set in the controller of the heating room (R), by the preset control setting through the set current temperature and set temperature. By automatically opening and closing the flow rate control bar 300, the flow rate of supplied or returned heating water is controlled.

The coupling part 320 has a branch nipple 330 installed so that the hot water supply pipe 210 and the hot water return pipe 220 can be easily installed by the branch nipple 330, and the smart sensor 310 measures the pressure and temperature of the heating water passing through the hot water return pipe 220 and transmits it to the controller.

In addition, the coupling part 320 is a first O-ring in which one side of the branch nipple 330 is completely screwed so that the first O-ring 340 can be installed where one end of the branch nipple 330 is located. It is configured to include a groove (not shown), and the first O-ring 340 is installed in the first O-ring groove formed on the inner periphery of the coupling part 320 so that one side of the branch nipple 330 is connected to the coupling part 320 . ) to prevent leakage between the coupling part 320 and one side of the branch nipple 330 after being completely screwed to the other side.

At this time, it is preferable that the first O-ring groove is formed so that one side of the branch nipple 330 is completely screwed and overlaps with a place where one end of the branch nipple 330 is located, which is the first O-ring 340 . ) is compressed by one end of the branch nipple 330 to form better watertightness.

In addition, the flow control valve 300 is configured to include a second packing 350 installed between the other end of the coupling part 320 and the branch nipple 330, the second packing (350) together with the first O-ring 340 realizes the effect of more efficiently preventing water leakage between the inner circumferential surface of the coupling part 320 and one side of the branch nipple 330 .

At this time, the coupling part 320 is formed at the other end, and includes a second packing groove (not shown) formed on the inner periphery, and the second packing 350 is installed in the second packing groove and the After one side of the branch nipple 330 is completely screwed to the other side of the coupling part 320, the first O-ring 340 and the first O-ring 340 and together to prevent

In addition, the second packing groove is formed on the inner periphery of the other end of the coupling part 320, and is preferably formed to be smaller than the diameter of the second packing 350, which is that the branch nipple 330 is As it is fully screwed to the other side of the coupling part 320, it is pressed by the branch nipple 330 to form better watertightness, and the branch nipple 330 is a nut coupling part 333 to be described in detail later. The second packing 350 is pressed by a step (not shown) formed by

In addition, the second packing 350 may be shaped in the form of an O-ring or a square ring, and accordingly, it will be apparent that the second packing groove is formed to correspond to the shape of the second packing 350 .

In relation to the above, a thread is formed on the inner circumferential surface of the coupling part 320 of the flow control valve 300 , the branch nipple 330 is formed on one side, and a thread is formed on the outer periphery, and the flow control valve The coupling part 320 of 300 is formed to extend to the other side of the coupling part 320 and to be coupled to the inner side 332, and to extend to the other side of the inner mouth 332, and to have a larger diameter than the inner mouth 332. A nut coupling part 333 for forming a stepped (not shown) on the outer periphery between the inner mouth part 332 and the other side of the inner mouth part 332 is formed to extend, and the same inner diameter as the inner mouth part 332 is formed. A press-fitting part 334 which is extended so as to form an insertion groove 334a into which one side of the hot water supply pipe 210 or the other side of the hot water return pipe 220 is inserted between the nut coupling part 333 and, Doedoe installed on the outer periphery of the press-fitting part 334, the press-in ring 336 and the nut coupling part installed so as to be located outside the outer periphery of one side of the hot water supply pipe 210 or the outer periphery of the other side of the hot water return pipe 220 It is screwed to the outer periphery of the 333, and is configured to include a fixing nut 338 for pressing the press-fit ring 336 as it is screwed to the outer periphery of the nut coupling part 333.

The inner part 332 is screwed to the coupling part 320 of the flow control valve 300 by having a thread formed on the outer periphery, and the nut coupling part 333 is press-fitted so that the fixing nut 338 is coupled. The hot water supply pipe 210 or the hot water return pipe 220 is fixed by the ring 336 so as to be coupled thereto.

The press-in part 334 is the hot water supply pipe 210 so that the hot water supply pipe 210 and the hot water return pipe 220 can be easily and stably installed and then fixed by the press-fit ring 336 and the fixing nut 338. and an insertion groove 334a into which one side of the hot water exchange pipe 220 can be inserted is formed.

The press-fit ring 336 is pressed as the fixing nut 338 screwed to the nut coupling part 333 is coupled, and the hot water supply pipe 210 and the hot water return pipe 220 inserted into the insertion groove 334a. The hot water supply pipe 210 and the hot water return pipe 220 are fixed and coupled to the branch nipple 330 by strongly close contact with the outer periphery of the , that is, by pressing. At this time, the structure in which the press-fit ring 336 is pressed by the fixing nut 338 may use any conventional structure, so a detailed description thereof will be omitted.

In addition, the branch nipple 330 is formed through the outer periphery of one side of the nut coupling part 333, and at least one display hole 335 which is formed through to be positioned at one end of the insertion groove 334a, It is installed inside the insertion groove (334a), is moved in one direction by the hot water supply pipe 210 or the hot water return pipe 220 inserted into the insertion groove (334a), and is made of a synthetic resin or metal material having elasticity. It will be apparent that the spherical identification tag 331 is included, and the identification tag 331 is composed of at least one corresponding to the number of the display holes 335 .

The identification tag 331 is inserted into the insertion groove 334a before one side of the hot water supply pipe 210 or the hot water return pipe 220 is fixed by the fixing nut 338 and the press-fit ring 336 and is coupled. Accordingly, it is moved to one side of the insertion groove 334a by one end of the hot water supply pipe 210 or the hot water return pipe 220 .

At this time, the display hole 335 is one side of the hot water supply pipe 210 or the hot water return pipe 220 when the identification tag 331 is moved in one direction by the hot water supply pipe 210 or the hot water return pipe 220 . The identification tag 331 is pressurized by the end to be stretched or contracted, and the operator confirms the identification tag 331 visually confirmed through the display hole 335 and then attaches the fixing nut 338 to the nut coupling part 333 ) so that the hot water supply pipe 210 or the hot water return pipe 220 is coupled to the branch nipple 330, so that the hot water supply pipe 210 or the hot water return pipe 220 is completely connected to the branch nipple 330. The effect of inserting and combining can be obtained.

In addition, the display hole 335 is characterized in that it is formed to be inclined in one direction toward the upper part, and thus the identification tag 331 is moved in one direction by the hot water supply pipe 210 or the hot water return pipe 220 . ) is more easily inserted, so that not only can the insertion of the hot water supply pipe 210 or the hot water return pipe 220 obtain a smooth effect, but also the insertion of the hot water supply pipe 210 or the hot water return pipe 220 is completely If not, the identification tag 331 is naturally moved back to the insertion groove 334a, so that the insertion state of the hot water supply pipe 210 or the hot water return pipe 220 can be more easily confirmed.

In addition, it is preferable that the width of the display hole 335 is formed to be slightly smaller than the diameter of the identification tag 331 , which is the identification tag 331 by the hot water supply pipe 210 or the hot water return pipe 220 . By fitting it into the display hole 335 when it is inserted into the display hole 335 , the effect of forming watertightness by the identification tag 331 is realized.

In addition, the identification tag 331 is characterized in that the color is distinguished from the color of the nut coupling part 333, which can confirm the state in which the identification tag 331 is inserted into the display hole 335 more reliably. effect can be obtained.

At this time, the inner peripheral surface of the nut coupling part 333 and the outer peripheral surface of the press-fitting part 334 are respectively formed in one direction or the other direction, that is, in the longitudinal direction, and the upper and lower portions of the identification tag 331 are inserted into guide grooves ( 333a) and 334b are preferably included, and the guide grooves 333a and 334b allow the spherical identification tag 331 to be guided in the other direction, that is, in one direction of the insertion groove 334a. (331) realizes the effect of smoothly moving in the display hole (335).

In addition, it is self-evident that the guide groove 333a formed on the inner peripheral surface of the nut coupling part 333 and the guide groove 334b formed on the outer peripheral surface of the press-fitting part 334 are formed to face each other, and the guide groove 333a ( 334b) will be self-evident that the number corresponding to the number of identification tags 331 is formed, and the guide groove 333a formed on the inner circumferential surface of the nut coupling part 333 and the hot water supply pipe 210 or the hot water return pipe ( 220 , when the identification tag 331 is inserted into the display hole 335 , it will be apparent that watertightness is formed by the lower portion of the identification tag 331 .

In addition, the press-fitting part 334 is configured to include at least one sealing groove (not shown) formed on the outer periphery where the guide groove 334b is not formed, and the branch nipple 330 is installed in the sealing groove. and a sealing member (not shown) to be formed, and the sealing groove and the sealing member have better watertightness by forming watertightness between the press-fitting part 334 and the hot water supply pipe 210 or the hot water return pipe 220 . to achieve the desired effect.

On the other hand, the branch nipple 330 has the insertion groove 334a so that it can be confirmed that the hot water supply pipe 210 or the hot water return pipe 220 is fully inserted instead of the display hole 335 and the identification tag 331 . It may be configured to include a pin clip 337 made of a metallic material having elasticity, one side of which is inserted and installed.

Specifically, the branch nipple 330 is installed with one side inserted into the insertion groove 334a, one end is bent vertically in the inward direction, that is, the press-in portion 334 direction, and the other side is fixed in the outer direction, that is, fixed. It is configured to include a pin clip 337 bent so as to be inclined in the direction of the nut 338 .

The pin clip 337 is bent by one end of the hot water supply pipe 210 or the hot water return pipe 220 as the hot water supply pipe 210 or the hot water return pipe 220 is inserted into the insertion groove 334a. One end is moved in close contact with the other side, and the other bent side is straightened by the insertion groove 334a between the hot water supply pipe 210 or the hot water return pipe 220 and the nut coupling part 333. is located In addition, the pin clip 337 may be formed in the shape of a general clip having the above structure, and may be formed in an annular shape as shown in the drawings.

At this time, when the hot water supply pipe 210 or the hot water return pipe 220 is completely inserted into the insertion groove 334a, the other end of the pin clip 337 is completely inserted into the insertion groove 334a, and thus the fixing nut By 338, the press-fit ring 336 is completely moved in one direction, that is, one side of the press-fit ring 336 is in close contact with the other side of the fixing nut 338, and the hot water supply pipe 210 or the hot water return pipe 220 ) is pressed and fixed, and the fixing nut 338 is completely coupled to the nut coupling part 333 at the same time.

However, if the hot water supply pipe 210 or the hot water return pipe 220 is not completely inserted into the insertion groove 334a, the other end of the pin clip 337 is not completely inserted into the insertion groove 334a. Since the press-fit ring 336 is not completely moved in one direction by the fixing nut 338, the fixing nut 338 is not completely coupled to the nut coupling part 333, so that an operator can use the hot water supply pipe 210 or the hot water return pipe. It is possible to obtain the effect of easily confirming that 220 is not completely inserted into the insertion groove (334a).

In addition, the pin clip 337 is characterized in that the straight length (L1) of the other end from the edge by the bent one end is the same as the length (H1) of the insertion groove (334a), which is the straight length ( When L1) is smaller than the length H1, the hot water supply pipe 210 or the hot water return pipe 220 is completely coupled to the fixing nut 338 even if the hot water supply pipe 210 or the hot water return pipe 220 is not fully inserted. ), it is difficult to ensure the complete insertion of the straight line length (L1) is greater than the length (H1), even if the hot water supply pipe 210 or the hot water return pipe 220 is completely inserted, the fixing nut 338 is Since it is not completely coupled, it is difficult to smoothly confirm the complete insertion of the hot water supply pipe 210 or the hot water return pipe 220, so it is preferable to be formed as described above.

At this time, the pin clip 337 is the insertion groove 334a and the hot water supply pipe 210 or hot water exchange after the hot water supply pipe 210 or the hot water return pipe 220 is completely inserted into the insertion groove 334a. The watertightness is formed between one side of the tube 220 to realize the effect of preventing water leakage.

In addition, the pin clip 337 is characterized in that the length (L2) of the bent one end is formed to be the same as the height (H2) of the insertion groove (334a), which is the length (L2) is the height (H2) When it is smaller or larger, when the hot water supply pipe 210 or the hot water return pipe 220 is inserted, not only is it bent inside the insertion groove 334a, but also does not move smoothly in one direction, so that the hot water supply pipe 210 or the hot water exchange Since the insertion of the pipe 220 may not be made smoothly, it is preferable to be formed as described above, and accordingly, one end of the pin clip 337 is one side of the hot water supply pipe 210 or the hot water return pipe 220 . It realizes the effect that the pin clip 337 can be moved in one direction of the insertion groove 334a after more stably close to the distal end.

In addition, the pin clip 337 may be formed in an annular shape, and may be formed in a plate-like shape like a general clip in another shape, and when formed in a plate-like shape, the same curvature as the curvature of the insertion groove 334a. It will be obvious that it is formed to have, on the other hand, when formed in a plate shape, it is preferable that a plurality of pieces are installed, and it is most preferable that at least two are installed.

As a result, the smart hybrid distributor with easy nipple coupling recognition of the present invention is a pipe to the branch nipple 330 of the flow control valve 300 installed in the branch pipe 200 to the hot water distributor 100, that is, the branch pipe 200 ) can be easily confirmed that it is fully inserted and combined in a combined state, that is, it is possible to improve work efficiency and prevent leakage due to insufficient coupling of the heating pipe, resulting in lapse of time defects You can get the effect that you can wear pants in advance In addition, the above-mentioned complete insertion and complete coupling means a state in which the corresponding components are closely or coupled to the limit point.

The above has been described with reference to a preferred embodiment of the present invention, and is not limited to the above embodiment, and a person skilled in the art through the above embodiment does not deviate from the gist of the present invention It can be implemented with various changes in

10: heating water supply source 100: hot water distributor
110: supply management 120: return management
200: branch pipe 210: hot water supply pipe
220: hot water return pipe 300: flow control valve
310: smart sensor 320: coupling part
330: branch nipple 331: dog tag
332: inner part 333: nut coupling part
334: press-fitting part 334a: insertion groove
335: display hole 336: press-fit ring
337; Pin clip 338: fixing nut
340: first O-ring 350: second packing

Claims (10)

The hot water distributor 100 receiving heating water from the heating water supply source 10; and
A branch pipe 200 having one side connected to the hot water distributor 100, and the other side passing through each heating room (R) and connected to the hot water distributor 100; and
It is installed between the hot water distributor 100 and the branch pipe 200, and has a smart sensor 310 that measures the pressure or temperature of hot water and the pressure and temperature, and the opening and closing amount is adjusted so that each heating room A flow control valve 300 for controlling the flow rate of heating water supplied to R);
The branch pipe 200 is
One side is connected to the hot water distributor 100, the other side is a plurality of hot water supply pipes 210 installed in each heating room (R), and one side of the plurality of hot water passing through each heating room (R) It is respectively connected to the other side of the supply pipe 210, and the other side is configured to include a plurality of hot water return pipes 220 connected to the hot water distributor 100,
The flow control valve 300 is
A coupling portion 320 protruding from the other side; and
A branch nipple 330 having one side coupled to the coupling part 320, the hot water supply pipe 210 or the hot water return pipe 220 being inserted and fixed; and
a first O-ring 340 installed between the coupling part 320 and one end of the branch nipple 330; and
The second packing 350 is installed between the other end of the coupling part 320 and the branch nipple 330;
The branch nipple 330 is
Formed on one side, the coupling part 320 of the flow control valve 300 is inserted into the other side of the inner inlet portion 332 is coupled; and
A nut coupling portion 333 extending to the other side of the inner portion 332 and extending so as to have a larger diameter than the inner portion 332; and
It is formed to extend to the other side of the inner inlet portion 332, and is formed to extend to form the same inner diameter as the inner inlet portion 332, and one side of the branch pipe 200 is inserted between the nut coupling portion 333 and A press-in portion 334 forming an insertion groove 334a; and
Doedoe installed on the outer periphery of the press-in portion 334, the press-in ring 336 is installed so as to be located outside the outer periphery of one side of the branch pipe (200); and
A fixing nut 338 that is screwed to the outer periphery of the nut coupling part 333 and presses the press-fit ring 336 as it is screwed to the outer periphery of the nut coupling part 333; Smart hybrid distributor with easy nipple coupling recognition, characterized in that.
delete delete According to claim 1,
The branch nipple 330 is
A display hole 335 that is formed through the outer periphery of one side of the nut coupling part 333, and is formed so as to be positioned at one end of the insertion groove 334a; and
Nipple coupling, characterized in that it comprises a; is installed in the insertion groove (334a), the identification tag (331) moved in one direction by the branch pipe (200) inserted into the insertion groove (334a); Recognizable smart hybrid dispenser.
5. The method of claim 4,
The display hole 335 is
Smart hybrid dispenser with easy nipple coupling recognition, characterized in that it is inclined in one direction toward the top.
6. The method of claim 5,
The display hole 335 is
When the identification tag 331 is moved in one direction by the branch pipe 200 , the identification tag 331 is inserted by one end of the branch pipe 200 . divider.
7. The method of claim 6,
The identification tag 331 is
A smart hybrid dispenser with easy nipple coupling recognition, characterized in that the color is different from the color of the nut coupling part (333).
According to claim 1,
The branch nipple 330 is
One side is installed inside the insertion groove (334a), one end is vertically bent in the inward direction, and the other end is bent so that the other side is inclined in the outward direction; a nipple characterized in that it comprises a; Smart hybrid dispenser with easy joint recognition.
9. The method of claim 8,
The pin clip 337 is
A smart hybrid dispenser with easy nipple coupling recognition, characterized in that the straight length (L1) of the other end from the edge by the bent one end is the same as the length (H1) of the insertion groove (334a).
10. The method of claim 9,
The pin clip 337 is
Smart hybrid dispenser with easy nipple coupling recognition, characterized in that the bent length (L2) of one end is formed equal to the height (H2) of the insertion groove (334a).

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