KR20090010547U - Recycle Part of Heating Description Device - Google Patents

Abstract

The present invention relates to a return portion of a heating distributor, which is one component of a heating facility such as a boiler, and provides a return portion of a heating distributor configured to increase energy efficiency by closing a valve when hot water returned is higher than a critical temperature. Its purpose is to.

The return portion of the heating distributor according to the present invention for achieving the above object is connected to the heat dissipation means as a return portion for flowing the heat transfer medium introduced from the heat dissipation means to the heating means, a longitudinal hollow is formed and the hollow inside A valve chamber having a larger diameter is formed and one side is integrally connected to the return portion and the valve body is connected to the heat dissipation means on the other side, and the disk which is located in the valve chamber to open or close the hollow formed in the valve chamber, A material of a shape memory alloy that expands and contracts according to temperature, and includes a coil spring for moving the disk while expanding and contracting according to a temperature of a heat transfer medium located inside the valve body and flowing along the hollow.

Description

Recovery part of heating distributor {Recycle Part of Heating Description Device}

The present invention relates to a return unit of a heating distributor, which is one component of a heating facility such as a boiler, and is configured to increase energy efficiency by closing a valve when hot water returned is higher than a critical temperature.

A typical heating facility includes a boiler for heating water, which is a heat transfer medium, and a plurality of heat dissipation means installed in a space to be heated and dissipating heat of hot water heated in the boiler to the room. It includes a water supply unit for connecting the boiler and the heat dissipation means for supplying hot water, and a return unit for discharging the heat of the hot water from the plurality of heat dissipation means and is returned to the boiler.

In addition, the water supply unit and the return unit is equipped with valves to supply water to the heat dissipation means and adjusts the amount of water recovered from the heat dissipation means.

1 is a front view showing a valve mounted on the water supply unit and the return unit according to the prior art, Figure 2 is a conceptual diagram showing an automatic valve mounted to the return unit according to the prior art.

As shown in FIG. 1, the valves mounted on the water supply unit 1 and the return unit 3 are ball valves 10, which open or close the ball valves 10 according to the rotational angle of the lever 11. Partial opening to regulate the amount of water passing through the ball valve 10.

The ball valve 10 mounted in the conventional return portion 3 configured as described above is directly operated by a manager and is returned regardless of the temperature of the hot water. That is, even if the hot water to be returned is a high temperature, the amount of return is controlled only by the opening degree of the ball valve 10.

On the other hand, as shown in Figure 2, the automatic valve 20 mounted on the return portion is provided on the stem 21 of the valve is a fluid temperature sensor 23 for sensing the temperature of the fluid passing through the valve chamber and Opening and closing the fluid passage of the valve in accordance with the signal transmission member 24 and the temperature signal of the fluid applied through the signal transmission member 24, which is connected to the fluid temperature sensor 23 for transmitting the detection signal And a temperature control device 25 for maintaining the fluid at the set temperature.

The automatic valve configured as described above operates smoothly at the beginning of the construction, but as time passes, the device is deteriorated or the operation is not performed properly due to external environmental factors, which causes problems in temperature control. In addition, the conventional valve has the disadvantage that the distance between the temperature control device and the fluid detection sensor is long, the configuration is complicated, the cost is expensive, and maintenance is inconvenient in the event of a failure.

The present invention is designed to solve the problems of the prior art as described above, when the hot water to be returned is higher than the threshold temperature to provide a return portion of the heating distributor configured to close the valve to increase the energy efficiency. There is this.

In addition, the present invention has a simple configuration of the valve formed in the return portion and there is almost no failure to provide an excellent return portion of the heating distributor excellent durability.

The return portion of the heating distributor of the present invention for achieving the above object is connected to the heat dissipation means in the return portion for flowing the heat transfer medium flowing from the heat dissipation means to the heating means, a longitudinal hollow is formed and the inside A valve chamber having a diameter larger than that of the hollow is formed and one side is integrally connected to the return portion and the valve body is connected to the heat dissipation means on the other side, and the disk is located in the valve chamber and opens or closes the hollow formed in the valve chamber. , A material of a shape memory alloy that expands and contracts according to temperature, and includes a coil spring that moves in the disk while being stretched according to a temperature of a heat transfer medium located inside the valve body and flowing along the hollow.

Further, according to a preferred embodiment of the present invention, the disk is formed in the middle of the length of the stem located along the hollow, the coil spring is wrapped around one side of the stem, one end of the coil spring in contact with the disk and the other end Is in contact with the inside of the valve body.

Further, according to a preferred embodiment of the present invention, the bias spring is wrapped around the other side of the stem, one end of the bias spring is in contact with the disk and the other end is in contact with the valve body.

In addition, according to a preferred embodiment of the present invention, the stem is supported in a state passing through a support member fixed to the valve body, the support member is a hole formed in the center to penetrate the stem, a hole formed in the center The space around which the heat transfer medium flows is formed.

In addition, according to a preferred embodiment of the present invention, the other side of the valve body is formed with a male screw and the coupler connected to the heat dissipation means is screwed to the male screw.

Further, according to a preferred embodiment of the present invention, the return portion and the valve body is brass.

As described above, when the temperature of the hot water to be returned is high enough to extend the coil spring of the shape memory alloy, the returning part of the heating distributor according to the present invention, by closing the valve valve by the coil spring, heat of the hot water in the heat radiating means It has enough heat radiation and high energy efficiency. Specifically, hot water at a low temperature flows into the return portion and flows to the return portion rather than flowing at high temperature to reduce heat loss, thereby improving energy efficiency.

In addition, the return portion of the heating distributor according to the present invention has a coil spring is opened and closed according to the temperature of the hot water to open and close the valve, the valve is integrally formed in the return portion, there is an advantage that the structure is simple and almost no failure. Conventional ball valves are passive, and automatic valves operated by fluid temperature sensors have a disadvantage in that the configuration is complicated and the failure rate is high, and the repair is difficult in the event of a failure.

1 is a front view showing a valve mounted on a water supply unit and a return unit according to the prior art,

Figure 2 is a conceptual diagram showing an automatic valve mounted on the return portion according to the prior art.

3 is a perspective view showing a return portion of the distributor for heating according to an embodiment of the present invention,

4 is a cross-sectional view showing a valve formed in the return portion shown in FIG.

5 is a conceptual diagram showing a relationship in which the disk of the valve shown in FIG. 4 operates according to the temperature of hot water,

6 is a front view of the support member shown in FIG. 3.

Explanation of symbols on the main parts of the drawings

1: water supply part 10: ball valve

30: boiler 100: valve

101: return unit 103: hose

110: valve body 111: hollow

113: valve chamber

117: male thread 122: step

132: coupler 140: stem

141: disk 150: support member

151: hole 153: space

160: coil spring 170: bias spring

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the return portion of the heating distributor according to the present invention will be described in detail.

In the drawings, Figure 3 is a perspective view showing a return portion of the heating distributor according to an embodiment of the present invention, Figure 4 is a cross-sectional view showing a valve formed in the return portion shown in Figure 3, Figure 5 is a valve shown in Figure 4 Is a conceptual diagram showing a relationship in which the disk of the operation according to the temperature of the hot water, Figure 6 is a front view of the support member shown in FIG.

As shown in FIG. 3, a plurality of valves 100 are integrally formed in the return portion 101, and a plurality of ball valves 10 are provided in the water supply portion 1. One end of the hose 103, which is a heat dissipation means installed in the space to be heated, is connected to the outlet of the ball valve 10, and the other end of the hose 103 is connected to the coupler 132 of the valve 100. . Therefore, the hot water heated in the boiler 30 flows into the water supply unit 1, and flows into the hose 103 according to the opening degree of the ball valve 10 from the water supply unit 1. And while flowing along the hose 103 to dissipate the heat of hot water into the room. The hot water cooled by the release of heat is introduced into the return portion 101 through the valve 100 and then flows back to the boiler 30 to be heated.

At this time, the heat of the hot water is discharged to the maximum in the room, it is efficient to minimize the amount of heat released from the heat radiation means other than the hose. In detail, if the hot water introduced to the return portion 101 through the valve 100 is relatively high, the heat is released from the hose as much as the efficiency is reduced.

To prevent this, as shown in Figures 4 and 5, the coil spring 160 made of a shape memory alloy inside the valve 100 is stretched by the temperature of the hot water to open and close the valve 100. Therefore, when the temperature of the hot water passing through the valve 100 is higher than the critical temperature, the valve 100 is closed. When the temperature of the hot water is lower than the critical temperature, the valve 100 is opened to open the valve 100. Allow the flow to the boiler (30).

Hereinafter, the valve configured as described above will be described in detail.

The valve 100 is integrally formed in the return portion 101 and the valve body 110 in which the hollow 111 is formed in the longitudinal direction, and the other end of the hose 103 is fastened to the lower end of the valve body 110. Connected coupler 132. Therefore, the hot water introduced through the hose 103 flows along the hollow 111 of the valve 100 and then flows into the return portion 101.

In addition, a valve chamber 113 having an extended structure is formed in the middle of the length of the valve body 110, and a male screw 117 is formed at a lower end of the valve body 110 such that the coupler 132 is a male screw 117. Screwed in.

On the other hand, the stem 111 is located in the hollow 111 of the valve body 110 in the longitudinal direction, the disk 141 is formed in the middle of the length of the stem 140. Here, the disk 141 is located in the valve chamber 113.

And the support member 150 is fixed to the upper end of the valve body 110 connected to the return portion (101). As shown in FIG. 6, the support member 150 has a central hole 151 formed therein so that an upper end of the stem 140 penetrates, and a plurality of supports 152 are radially circumscribed around the central hole 151. It extends to form a space 153 between the support 152 and the support 152. An end of the support 152 is fixed to the valve body 110 and the hot water flows to the return portion 101 through the space 153.

Meanwhile, a coil spring 160 made of a shape memory alloy is disposed around the stem 140 around the disk 141 formed on the stem 140, and a bias spring 170 is disposed below the disk 141. ) Is wrapped around the stem 140. Here, the lower end of the coil spring 160 is in contact with the upper surface of the disk 141 and the upper end of the coil spring 160 is in contact with the support member 150.

Meanwhile, a step 122 is formed at a lower end of the hollow 111, and a bottom of the bias spring 170 is in contact with the step 122, and an upper end of the bias spring 170 is in contact with a bottom of the disk 141. It provides an elastic force to push the disk 141 upward. Therefore, the stem 140 is moved up and down by the elasticity of the coil spring 160 and the elasticity of the bias spring 170 to open or close the hollow 111 formed in the valve chamber 113.

Hereinafter, the structure of the valve body 110 formed integrally with the return portion 101 will be described in detail. The valve body 110 is formed with a valve chamber 113 in which the disk 141 is located. The diameter of the disk 141 is larger than the hollow 111 formed in the valve chamber 113, the disk 141 located in the valve chamber 113 moves up and down along the stem 140, the valve chamber ( The hollow 111 formed in 113 is opened or closed.

Specifically, when the elastic force of the coil spring 160 is greater than the elastic force of the bias spring 170, the stem 140 moves downward to close the hollow 111 formed in the valve chamber 113 to close the disk 141. On the contrary, when the elastic force of the coil spring 160 is smaller than the elastic force of the bias spring 170, the stem 140 moves upward to open the hollow 111 formed in the valve chamber 113.

In the return portion 101 of the heating distributor, the coil spring 160 made of the shape memory alloy is stretched according to the temperature, the elastic force when the length of the coil spring 160 is extended is bias spring 170 The elastic force of the coil spring 160 is larger than the elastic force of the coil spring 160. However, the elastic force of the coil spring 160 is smaller than the elastic force of the bias spring 170.

Therefore, when the temperature of the hot water is hot and exceeds the threshold temperature, the coil spring 160 extends to close the hollow 111 formed in the valve chamber 113. However, when the temperature is less than the critical temperature, the coil spring 160 contracts to form a valve chamber. The hollow 111 formed in the 113 is opened.

That is, the valve 100 is closed when the temperature of the hot water is high based on the critical temperature of the coil spring 160 made of the shape memory alloy, and the valve 100 is opened when the temperature of the hot water is low. Therefore, the hot water flows to the return portion 101 or the flow is blocked according to the temperature of the hot water introduced into the valve 100.

When the hot water exceeds the critical temperature in the return portion 101 of the heating distributor according to the present invention configured as described above, the hot water stays in the space to be heated to sufficiently radiate heat to improve thermal efficiency.

Claims (6)

In the valve formed in the return portion 101 is connected to the heat dissipation means for flowing the heat transfer medium introduced from the heat dissipation means to the heating means, A hollow body 111 is formed in the longitudinal direction and a valve chamber 113 having a larger diameter than the hollow is formed therein, and one side is integrally connected to the return portion and the heat dissipation means is connected to the other side. A disk 141 located in the valve chamber for opening or closing a hollow formed in the valve chamber; A material of a shape memory alloy that expands and contracts according to temperature, wherein the coil spring 160 moves inside the valve body and moves according to a temperature of a heat transfer medium flowing along the hollow. Return part of the distributor for heating. The method of claim 1, The disk is formed in the middle of the length of the stem 140 located along the hollow, the coil spring is wrapped around one side of the stem, one end of the coil spring is in contact with the disk and the other end is in contact with the inside of the valve body A return unit of the distributor for heating. The method of claim 2, A bias spring (170) surrounds the other side of the stem, and one end of the bias spring is in contact with the disk and the other end is in contact with the inside of the valve body. The method according to claim 2 or 3, The stem is supported while penetrating the support member 150 fixed to the valve body, and the support member has a hole 151 formed therein so that the stem penetrates in the center thereof, and the heat transfer around the hole formed at the center thereof. Return portion of the heating distributor, characterized in that the space in which the medium flows 153 is formed. The method of claim 4, wherein The other side of the valve body is a male screw 117 is formed and the return portion of the heating distributor, characterized in that the coupler 132 connected to the heat dissipation means is screwed to the male screw. The method of claim 5, The return portion and the return portion of the heating distributor, characterized in that the valve body is brass.