KR20100097945A - Flux control valve for heating system - Google Patents

Abstract

PURPOSE: A flux control valve for heating system is provided to control the opening area of a flow path and enable minute flow control by controlling a gap between a control member and a valve portion. CONSTITUTION: A flux control valve for heating system comprises a socket of a hollow tube shape and an adjusting member of a hollow tube shape. One end of a socket is connected to the header of a distributor and a collector of a heating system. A ring-shaped valve portion(112) is projected from the inner surface of a hollow portion of the socket. A part of the adjusting member is inserted into the inside of the hollow portion of the socket. The other part of the adjusting member is connected to the heating pipe.

Description

Flux control valve for heating system

The present invention relates to a valve for controlling the flow rate of the heating water of the heating system, and more particularly, installed in a hot water distributor for distributing the heating water to each room to distribute the flow rate of the heating water distributed to each room or recovered from each room. The present invention relates to a flow control valve for a heating system that controls a flow rate of heating water that is precisely and efficiently controlled.

Currently, heating pipes with heating water flows on the floor of a room or living room as a way of heating residential spaces such as houses or apartments in Korea, and heating the floor by supplying heating water heated by a boiler through heating pipes. This is mainly used.

This heating system supplies the heating water heated by the boiler to the hot water distributor for heating, heats the indoor floor while the heating water passed through the hot water distributor for heating flows through the heating pipe installed on the floor, and then the heat-exchanged heating water is returned to the hot water distributor for heating. After the return is introduced into the boiler through the recovery pipe and heated again, the residential space is heated by recirculating through the above process.

This heating system will be described in more detail with reference to FIGS. 1 and 2 of the accompanying drawings.

1 is a layout view showing an example of a conventional heating piping structure, the heating water heated in the boiler (B) is supplied to the hot water distributor (2) via the supply pipe (1), for heating supplied to the hot water distributor (2) Water is distributed through heating pipes 5 connected to places where heating is required (eg, bedroom 1, bedroom 2, bedroom 3, family room, balcony, study, etc.) to heat places that require heating. The heating water cooled by heat exchange in the heating pipe 5 in the place where heating is required is introduced into the collector 3 and collected, and then recovered and reheated to the boiler B along the drain pipe 4.

On the other hand, the recovery device (3) is provided with a flow control valve (3c) for controlling the flow rate of the heating water flowing along the heating pipe (5) in the portion connected to each heating pipe (5).

FIG. 2 shows the configuration of the recovery device 3 located in the A portion of FIG. 1, wherein the recovery device 3 includes a header 3a in which a plurality of recovery ports 3b are formed along the longitudinal direction, and the header 3a. It is composed of a flow control valve (3c) is installed in each of the recoverers (3) to connect the heating pipe (5) connected to the place where heating is required and the header (3a). One end of the header 3a is connected to the drain pipe 4 to send the heating water introduced from the heating pipes 5 to the drain pipe 4.

The flow control valve 3c includes a hollow body portion 3d in which a flow path for heating water flows is formed, and a shaft 3e extending radially in a flow path (not shown) of the body portion 3d. And rotatably installed around the control plate (not shown) for adjusting the opening area of the flow path (not shown), and coupled to the shaft 3e of the control plate (not shown) outside the body portion 3d. It consists of the knob 3f which adjusts the position of a control plate (not shown).

In the conventional flow control valve 3c configured as described above, the user rotates the knob 3f from the outside to change the position of the control plate (not shown), thereby adjusting the area of the flow path (not shown), thereby adjusting the flow path (not shown). Adjust the flow rate of the heating water flowing through.

However, the conventional flow control valve as described above has the following problems.

First, since the shield plate is adapted to adjust the open area of the flow path on the flow path, precise flow rate control is not achieved.

Second, since the heating water flowing along the flow path hits the shielding plate and then flows by bypassing the shielding plate, not only the noise is severely generated but also the shielding plate acts as a resistance, so that the heating water flows smoothly. There is.

The present invention is to solve the above problems, an object of the present invention is to control the flow rate precisely, it is possible to reduce the noise, as well as the flow control valve for a heating system that is easy to manufacture and reduce the production cost In providing.

The present invention for achieving the above object, and one end is connected to the header of the distributor or distributor of the heating system, and the hollow tube-type socket is formed in the inner circumferential surface of the hollow portion is formed so that the ring-shaped valve portion protrudes radially inwardly; ; A portion of the portion inserted into the hollow portion of the socket, the portion being spirally coupled to the socket while being inserted into the hollow portion of the socket, and the other portion is connected to the heating pipe, It provides a flow control valve for a heating system comprising a control member in the form of a hollow tube for adjusting the opening area of the flow path by adjusting the distance between one end and the valve portion.

According to the present invention, the adjusting member moves in the axial direction while rotating in a spiral with respect to the socket to adjust the distance between the adjusting member and the valve portion, thereby adjusting the open area of the flow path to control the flow rate. Therefore, the flow rate adjustment is made very finely and precisely.

In addition, since the heating water flowing in the axial direction along the hollow portion of the adjusting member and the socket flows smoothly without being blocked, almost no noise is generated due to interference, and smooth flow can be ensured, thereby improving the overall efficiency of the heating system. There is an advantage.

In addition, since the flow control valve can be configured only by the socket and the adjustment member, there is an advantage that the structure is simplified and the manufacturing cost can be greatly reduced.

Hereinafter, a preferred embodiment of a flow control valve for a heating system according to the present invention will be described in detail with reference to the accompanying drawings.

3 to 5b illustrate an embodiment of a flow control valve applied to a recoverer of a heating system. As shown in FIG. 3, the recoverer 3 has a plurality of recovery ports 32 along a lengthwise direction thereof. It is composed of a plurality of flow control valve 100 is formed in the header 31 and coupled to each recovery port 32 of the header 31 to connect the heating pipe 5 and the header 31.

The recovery holes 32 of the header 31 are formed to protrude a predetermined length in the lower portion of the header 31, and the thread 33 to which the flow control valve 100 is spirally coupled is formed on the outer peripheral surface of the distal end portion.

4 and 5A and 5B, the flow control valve 100 includes a hollow fixing socket 110 having one end spirally coupled to the recovery port 32 of the header 31, and the fixing socket. Ring-shaped connection socket 120 is coupled to the other end of the 110, and the adjustment member that is helically coupled to the connection socket 120 is rotated by the user to move axially with respect to the connection socket 120 ( 130).

The fixing socket 110 has a ring-shaped valve portion 112 protruding in the axial center direction on the inner peripheral surface of the hollow portion 111. The valve portion 112 is a portion for adjusting the flow rate through the distance from one end of the adjustment member 130, the adjustment member 130 so as to be in contact with one end of the adjustment member 130 to close the flow path. It has an inner diameter slightly smaller than the outer diameter of one end of the). The valve portion 112 is preferably formed to be inclined to the surface toward the control member 130 so that the heating water flowing through the control member 130 can flow smoothly toward the recovery port (32).

A first screw thread 113 is formed on the inner circumferential surface of one end of the fixed socket 110 and is helically coupled to the screw thread 33 of the recovery port 32. The connecting socket is formed on the outer circumferential surface of the other end of the fixed socket 110. The second screw thread 114 to which the 120 is spirally coupled is formed.

The connecting socket 120 is a component that connects the fixed socket 110 and the adjustment member 130, the inner peripheral surface of one end is helically coupled to the second screw thread 114 of the fixed socket 110 One screw thread 122 is formed, and a second screw thread 123 to which the adjusting member 130 is spirally coupled is formed on the inner circumferential surface of the other end.

The first screw thread 122 and the second screw thread 123 of the connecting socket 120 are formed to have different diameters, and the stepped portion 124 is formed between the first screw thread 122 and the second screw thread 123. ) Is formed. On the stepped portion 124, an O-ring-shaped packing member 140 is placed to maintain airtightness between the fixed socket 110 and the connection socket 120.

The adjusting member 130 adjusts the flow rate by adjusting an interval between the upper end portion and the valve portion 112 of the fixed socket 110 while moving in the axial direction with respect to the connection socket 120 and the fixed socket 110. do. In this embodiment, the adjusting member 130 has a hollow body portion 131 formed on the outer peripheral surface of the middle portion formed with a first screw thread 133 which is spirally coupled to the second screw thread 123 of the connecting socket 120. On the outer circumferential surface of the lower end of the body portion 131, a second screw thread 137 is formed to be spirally coupled to the socket 6 of the heating pipe 5. Between the first screw thread 133 and the second screw thread 137, a skirt portion 136 contacting the lower end of the connecting socket 120 or the upper end of the socket 6 of the heating pipe 5 protrudes radially outward. It is formed.

The bottom of the hollow portion of the body portion 131 is open, the top of the hollow portion is closed by the shielding plate 134, the side portion of the upper end of the body portion 131, strictly speaking, immediately below the shielding plate 134 An outlet 135 is formed to allow the heating water to flow. Here, only one outlet port 135 may be formed, but a plurality of outlets 135 may be formed at a predetermined interval. The shield plate 134 is preferably made of a dome or conical shape concave downward to facilitate the flow of the heating water.

In addition, an upper portion of the body portion 131, for example, just below the outlet 135, a stop ring 138 for restricting the lowering position of the adjustment member 130 is formed to protrude radially outward. The stop ring 138 controls the lowering position of the adjusting member 130 while the adjusting member 130 is in contact with the packing member 140 or the stepped portion 124 of the connecting socket 120 when the lowering movement (adjusting member ( 130 serves to prevent the departure from the connection socket 120.

The flow control valve 100 configured as described above operates as follows.

First, Figure 5a is coupled to the upper side of the connecting socket 120 to the adjustment member 130 of the flow control valve 100 in a state in which the flow path is completely closed, the shield plate 134 outer periphery of the upper end of the adjustment member 130 While the edge contacts the inner circumferential edge of the valve portion 112 of the fixed socket 110, the flow toward the recovery port 32 is blocked by completely blocking the inner circumference of the valve portion 112.

When the user rotates the adjustment member 130 with respect to the connection socket 120 in this state, the adjustment member 130 is moved along the axial direction, as shown in Figure 5b and the upper end of the adjustment member 130 and the fixed socket The valve portion 112 of the 110 is spaced a predetermined distance to form a space between the two.

At this time, the heating water recovered through the heating pipe (5) flows through the hollow portion of the adjusting member 130, the inside of the hollow 111 of the fixed socket 110 through the outlet 135 of the upper end of the adjusting member (130). After flowing in, it is introduced into the header 31 (see Fig. 3) through the recovery port (32).

As described above, the flow control valve 100 of the present invention, the user rotates the adjustment member 130 in a spiral with respect to the connecting socket 120 in the axial direction with respect to the connecting socket 120 and the fixed socket 110. By moving the position, thereby adjusting the separation distance between the outer peripheral portion of the upper end of the adjusting member 130 and the valve portion 112 to adjust the flow path area. That is, in order to increase the flow rate of the heating water, by rotating the control member 130 in one direction (for example, clockwise) to move the control member 130 to the lower side and the fixed socket ( In order to increase the distance from the valve portion 112 of the 110 and, on the contrary, to reduce the flow rate of the heating water, the adjusting member 130 is rotated in the opposite direction (for example, counterclockwise) as before. By moving the upper side to narrow the interval between the upper end of the adjusting member 130 and the valve portion 112 of the fixed socket 110.

As described above, in the flow control valve 100 of the present invention, the adjustment member 130 moves in the axial direction by one pitch of the screw thread during one rotation of the adjustment member 130, and thus, between the upper end of the adjustment member 130 and the valve portion 112. Since the interval is adjusted, the passage area can be finely and precisely adjusted.

In addition, the heating water flowing into the hollow part 132 of the adjusting member 130 flows out through the outlet 135 formed at the upper end side of the adjusting member 130 and then the valve 112 and the upper end of the adjusting member 130. It flows through the open spaces in between, so it can flow smoothly with little resistance. Therefore, there is an advantage that can significantly reduce the noise compared to the conventional.

On the other hand, although not shown in the drawings, in order to more precisely control the flow rate through the adjusting member 130, inscribed on the outer surface of the body portion 131 of the adjusting member 130 to position the position of the adjusting member 130 You may be able to make more precise adjustments.

The flow control valve 100 of the above-described embodiment is applied to the recovery system 3 of the heating system to adjust the flow rate of the heating water flowing through the heating pipes 5, but the flow control valve of the present invention ( 100 may be applied to the distributor 2 of the heating system (see FIG. 1) to precisely control the heating degree of each place requiring heating by adjusting the flow rate of the heating water supplied to each heating pipe 5. will be.

Meanwhile. Prior to explaining the configuration of another embodiment of the present invention, the description of the parts and the operation made in the same manner as the configuration is omitted, and the same reference numerals are applied.

6 and 7a and 7b of another embodiment of the present invention, the adjusting member 130, the hollow body portion 131; The shield plate 134 for opening and closing the valve portion 112 of the fixed socket 110 by the vertical movement of the body portion (131); Helix is coupled to the center of the shielding plate 134, the spirally rotates relative to the valve 112 in the axial direction in accordance with the rotation direction of the control member 130 to adjust the interval between the valve 112 It is configured to include an auxiliary shield plate 160 for adjusting the open area of the flow path through.

A plurality of guide pins 161 protruding are formed on an upper surface of the auxiliary shielding plate 160, and guides to prevent rotation while guiding vertical movement of the guide pins 161 on the open inner circumferential surface of the valve part 112. The hole 125 is formed to correspond.

The spiral hole 139 formed at the center of the shielding plate 134 is spirally coupled by the fastening member 162 formed at the center of the auxiliary shielding plate 160.

The flow control valve 100 configured as described above operates as follows.

First, FIG. 7A completely closes the inner circumference of the valve unit 112 while the outer circumferential edge of the auxiliary shielding plate 160 of the upper end of the adjustment member 130 contacts the inner circumference of the valve unit 112 of the fixed socket 110. Flow toward the recovery port 32 is blocked.

In this state, when the user rotates the adjusting member 130 with respect to the connection socket 120, the adjusting member 130 is idle, and the secondary shield coupled to the spiral hole 139 of the shielding plate 134 The plate 160 is guided to the guide hole 125 of the valve portion 112 so as not to rotate when moved up and down along the axial direction, so that the adjustment member 130 as shown in Figure 5b The upper end portion and the valve portion 112 of the fixed socket 110 is spaced apart a predetermined distance is formed between the two.

Therefore, the flow control valve 100 of the present invention is applied to the distributor 2 (see FIG. 1) of the heating system, as described in the above description of the operation, the flow rate of the heating water supplied to each heating pipe (5). By adjusting, you will be able to precisely control the heating level in each place that needs heating.

1 is a layout view showing a piping structure of a general heating system

Figure 2 is a front view showing the structure of a flow control valve configured in a conventional recovery machine

3 is a perspective view of a recoverer of a heating system to which a flow control valve is applied according to an embodiment of the present invention;

4 is an exploded perspective view showing the structure of an embodiment of a flow control valve according to the present invention;

5A and 5B are cross-sectional views illustrating the structure and operation of the flow control valve of FIG. 4. FIG. 5A shows a state in which an adjustment member of the flow control valve is completely closed, and FIG. 5B shows an adjustment member of the flow control valve. Indicates a state in which the flow path is completely opened.

Figure 6 is an exploded perspective view showing the structure of another embodiment of the flow control valve of the present invention

7A and 7B are cross-sectional views illustrating the structure and operation of the flow control valve of FIG. 4. FIG. 7A shows a state in which an adjustment member of the flow control valve is completely closed, and FIG. 7B shows an adjustment member of the flow control valve. Indicates a state in which the flow path is completely opened.

Explanation of symbols on the main parts of the drawings

30: Recover 31: Header

32: recovery port 33: thread

100: flow control valve 110: fixed socket

112: valve portion 120: connecting socket

124: stepped portion 125: guide hole

130: adjustment member 131: body portion

132: hollow portion 133: first screw portion

134: shield plate 135: outlet

136: skirt portion 138: stop ring

139: spiral hole 140: packing member

160: auxiliary shield plate 161: guide pin

162: fastening member

Claims (10)

A socket in the form of a hollow tube, one end of which is connected to the header of the distributor or the collector of the heating system, the ring-shaped valve portion projecting radially inwardly on the inner circumferential surface of the hollow portion; One end of the part inserted into the hollow part of the socket while a part is coupled to the socket while being inserted into the hollow part of the socket, the other part is connected to the heating pipe, and is moved axially while rotating with respect to the socket. And a control member in the form of a hollow tube for adjusting an opening area of the flow path by adjusting a gap between the valve unit and the valve unit. The method of claim 1, The adjusting member, A hollow body portion; A shielding plate installed to close one end of the hollow part of the body part in an axial direction and open and close a valve part of the socket by vertical movement of the body part; Flow control valve for a heating system, characterized in that it comprises a discharge port formed in communication with the hollow portion of the socket on one end side of the body portion. The method of claim 2, The shielding plate is a flow control valve for a heating system, characterized in that the concave dome shape or conical shape toward the inside of the hollow portion of the body portion. The method according to claim 1 or 2, A screw thread is formed inside the socket, and a thread thread coupled to a screw thread of the socket is formed on an outer circumferential surface of the adjusting member. The method of claim 1, The adjusting member, A hollow body portion; The shielding plate for opening and closing the valve portion of the socket by the vertical movement of the body portion; Spirally coupled to the center of the shield plate, And an auxiliary shielding plate configured to move in the axial direction while spirally rotating with respect to the valve unit according to the rotational direction of the control member to adjust the opening area of the flow path by adjusting the gap between the valve units. The method of claim 5, A plurality of guide pins protruding from the upper surface of the auxiliary shielding plate are formed, and a guide hole for preventing rotation while guiding the vertical movement of the guide pins is formed on the open inner circumferential surface of the valve unit. Flow control valve. The method of claim 1, The socket is a heating socket, characterized in that the fixing socket is fixedly coupled to the header, one end is fixedly coupled to the fixed socket and the other end of the connection socket is formed with a screw thread is formed on the inner circumferential surface the spiral member is coupled Flow control valve. The method of claim 7, wherein The coupling portion of the fixed socket and the connecting socket is a flow control valve for a heating system, characterized in that the ring-shaped packing member is installed to prevent leakage. The method of claim 8, A flow control valve for a heating system, characterized in that a stop ring is provided on the outer circumferential portion of the regulating member to contact the packing member to limit the positional movement of the regulating member. The method of claim 1, The valve portion flow rate control valve for a heating system, characterized in that the inclined surface toward the adjustment member.

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