KR101096752B1 - Automatic temperature regulating taper valve - Google Patents

Abstract

The present invention relates to a thermostatic taper valve to maintain a constant temperature of the fluid, the inlet (110a) is formed on one side and the outlet (110b) is formed on the other side and the valve chamber 110 so that the fluid flows therein Valve body 100 is provided; A valve guide 120 supported by a stop ring at an outlet side of the valve body and provided in a space of a valve chamber; A valve disc 130 that is inserted into the inner circumferential surface of the valve guide and flows; A shape memory expansion spring (140) having one side supported by the flange side of the valve guide and the other side being in contact with the inner surface of the valve disc to expand according to the temperature of the fluid; A tapered compression spring 150 is coupled between the spring support end of the valve disc and the spring latch end of the valve body to act on the valve disc to contract the shape memory expansion spring toward the outlet. Depending on the flow amount is variable, the temperature is automatically adjusted.

In particular, the valve face of the valve disc and the disc seat of the valve body are tapered, so the flow rate is finely adjusted and the flow of fluid is stabilized so that noise is not generated.

 Valve body, valve guide, valve disc, shape memory expansion spring, taper compression spring, thermostatic taper valve

Description

Automatic temperature regulating taper valve

The present invention relates to a thermostatic taper valve in which the flow rate is appropriately finely adjusted automatically according to the temperature of the fluid by changing the distance between the valve disk and the disc seat in a tapered shape, and the flow of the fluid is stable. will be.

Commonly used thermostatic valves are components of equipment systems that block fluids or control flow rates by a set temperature mounted on hot water distributors of heating supply systems such as central heating, district heating, and individual heating.

In the prior art, a thermostatic valve of 1 degree to 2 degrees using the characteristics of the shape memory alloy as a fixed valve set to a constant temperature is registered in the patent publications 10-0742656 and 10-0779516.

These valves are capable of proportional control of the magnetic force by sensing the water temperature, and despite the product having a favorable performance for energy saving, the reliability of the product has not been secured due to the problem to be solved. As the automatic temperature control valve equipped with the inertia type driving device based on the developed temperature sensing is rapidly spread, the situation is greatly disregarded by the user in the reality that convenience of use is required rather than practicality of energy saving.

1 degree water temperature sensing type thermostat valve has a valve body 10 is formed with an inlet 11 and outlet 12 through which the heated hot water flows in and out, the valve chamber 13 is formed therein; A shape memory element 20 coupled to the valve chamber 13 to expand or contract according to the temperature of the fluid; A disk member 30 through which an inner diameter is passed; An elastic member 40 for supporting the disk member and the shape memory element; A coupling part communicating with the valve chamber is formed and the seat member 50 is formed with a seat surface inwardly of the coupling part.

Heating water flow control valve of the water temperature sensing type of 2 degrees, and the water supply fastening portion 10 of the tubular shape screwed to the fastening portion of the distribution water supply; A tubular body 20 formed at one side and having a pipe fitting portion to which a heating pipe is coupled; One side end of the body 20 is installed so as not to be separated, the first joint 30 to couple the water supply fastening portion 10 with the body 20; A tightening ring 40 fitted to an outer circumference of the heating pipe fitted to the pipe fitting portion; A second joint (50) for tightening the fastening ring (40) to prevent the heating pipe from being separated from the pipe fitting portion (21); A shape memory spring (70) positioned at the water supply fastening portion (10) in the body (20); An elastic spring (80) positioned inside the pipe fitting portion (21) in the body (20); It is configured between the shape memory spring 70 and the elastic spring 80 is composed of a ball valve 90 of the hat-shaped round end.

[Document 1] Registered Patent Publication No. 10-0742656 (2007.7.19) Automatic temperature control valve

[Document 2] Registered Patent Publication No. 10-0779516 (2007.11.20) Heating water flow control valve

In the thermostat valve shown in FIG. 1, when the temperature of the heating water is higher than the set temperature, the shape memory device 20 expands to press the disk member 30 toward the seat member 50 to block the flow of fluid. Although the flow rate is minimized, the disk member 30 has a flat shape perpendicular to the longitudinal direction of the valve body 10, and the seat portion 52 of the seat member 50 has a spherical ball valve shape. As illustrated in the flow rate characteristic diagram of FIG. 1, the disk member 30 and the sheet member 50 have a problem in that the flow rate is controlled or blocked only at a near minimum range, and the flow rate is not smoothly adjusted outside the minimum range.

In addition, when the outer circumferential surface of the disk member 30 having a large outer diameter flows a predetermined length from the inner circumferential surface of the valve body 10, the scale is caught or parallel between the outer circumferential surface of the disk member 30 and the inner circumferential surface of the valve body 10. If the contact force is increased out of the problem is a problem that the valve does not operate due to the poor flow state.

The heating water flow control valve shown in FIG. 2 has a structure and a function similar to those of the thermostat valve shown in FIG. 1 and thus serves as the cylindrical disk member 30 and the seat member 50 of FIG. The seat face of the ball valve 90 and the outlet 21a of the body 20 has a planar shape perpendicular to the longitudinal direction of the body 20, so that the ball valve 90 as illustrated in the flow characteristic diagram of FIG. Flow rate is controlled or blocked only in the minimum range close to the seat surface of the outlet and the outlet (21a), the flow rate is not smoothly adjusted outside the minimum range.

The present invention for solving the above problems, the central heating method, the district heating method and the individual heating method, such as the heating section of the hot water distributor of the heating supply system, such as the flow rate suitable for a predetermined temperature is finely adjusted automatically A thermostatic taper valve capable of automatically adjusting the temperature of a gas, comprising: a valve body (100) having a valve chamber for flowing fluid in a straight line from an inlet to an outlet; A valve guide 120 supported by a stop ring installed at an outlet of the valve body and provided in a space of the valve chamber; A valve disc 130 that is inserted into the inner peripheral surface space of the valve guide and flows; A shape memory expansion spring 140 having one side supported by the valve guide and the other side being in contact with the inner surface of the valve disc to expand in accordance with the temperature of the fluid; And a tapered compression spring 150 coupled with a compressed force between the spring support end of the valve disc and the spring latch end of the valve body to push the valve disc to contract the shape memory expansion spring toward the outlet. The valve seat and the disk seat of the valve body are tapered to provide a thermostatic taper valve in which the flow rate is finely adjusted and the fluid flow is stabilized due to the change of the valve gap at a predetermined flow distance. .

The gap between the tapered disk seat formed on the inner surface of the valve chamber of the valve body and the valve surface of the valve disk is changed and finely adjusted to the flow amount suitable for the predetermined temperature, so that the reliability of the product is high and the energy saving effect is excellent. to be.

In addition, the valve guide, valve disc, shape memory expansion spring, and tapered compression spring are combined with layer layers in the circumferential space of the valve chamber, so that the length of the valve body can be shortened, thus reducing the manufacturing cost and heating water of the existing heating system. It is possible to replace the general ball valve installed in the dispenser with the present invention can reduce the construction cost and energy savings.

Referring to the thermostatic taper valve according to the present invention with reference to the accompanying drawings as follows.

Description of the main parts of the drawings

100: valve body 100a: disc seat

110: valve chamber 110a: inlet

110b: outlet 120: valve guide

130: valve disc 140: shape memory expansion spring

150: tapered compression spring 160a, b: stop ring a, b

In the thermostatic taper valve of the present invention, as shown in FIG. 3, a valve chamber 110 is formed to flow fluid from the inlet port 110a to the outlet port 110b in a straight direction to form the valve body 100. Doing.

On the other hand, in the valve chamber 110 in contact with the inlet (110a) side of the valve body 100, a disc seat (100a) is formed in a tapered shape having a predetermined angle and the disc seat (100a) The inner circumferential surface in contact with the tip of the tapered portion is formed with a spring hook end (100b), the groove (100c) to fit the hole stop ring (160a, b) to the inner circumferential surface of the valve chamber 110 toward the outlet (110b) , d).

One side of the stop ring 160a fitted to the groove 100c formed on the inner circumferential surface of the valve chamber 110 on the outlet 110b side of the valve body 100 and one of the stop rings 160b fitted to the groove 100d. A flange 120b is formed to be supported by the stop rings 160a and 160b between the side surfaces, and the surface of the flange 120b penetrates through a plurality of holes 120d so that fluid introduced into the valve chamber can flow. One side central portion of the flange 120b constitutes a valve guide 120 formed of a cylindrical guide tube 120a.

The guide tube 120a of the valve guide 120 has a plurality of holes 120c having inner and outer circumferential surfaces such that the fluid introduced into the valve chamber 110 from the inlet 110a flows into the hole penetrated through the center of the flange 120b. Penetrated through).

The disk shaft (130b) is formed so as to slide on the inner circumferential surface of the guide pipe (120a) of the valve guide 120 by a predetermined distance in accordance with the temperature change of the fluid and the valve surface (130a) in contact with the disk shaft (130b) A tapered disc is formed to finely control the flow rate by a change in the gap with the disc seat 100a formed in the valve body 100, and at one end of the valve surface 130a in contact with the disc shaft 130b. A cylindrical support tube 130c is formed in the longitudinal direction so that the fluid introduced into the valve chamber 110 flows toward the guide tube 120a of the valve guide 120 and passes through the plurality of holes 130e. At the end of the support tube 130c, a valve disc 130 formed of a spring support end 130d is formed.

After the shape memory expansion spring 140 is fitted to the outer circumferential surface of the guide tube 120a of the valve guide 120, the front end is supported by the side surface of the flange 120b of the valve guide 120 and the rear end of the valve disc 120 It is comprised so that the inner side surface of the valve surface 130a of 130 may be contacted.

After the tapered compression spring 150 is fitted into the outer circumferential surface space portion of the support tube 130c of the valve disc 130, the end of the small diameter is supported by contacting the spring support end 130d of the valve disc 130. The end of the diameter is configured to be supported in contact with the spring hook end of the valve body (100).

On the other hand, the valve of the prior art is 1 degree as shown in 2 to 2 degrees; seat member 50, 2 degrees; 1 degree at the front and rear end relative to the ball valve 90; elastic member 40, 2 degrees; elastic spring 80 and 1 degree; mold suppressing element 20, 2 degree; by providing the mold retaining spring 70 in a straight line (in series), the length of the valve is long, and the valve surface is circular 1 degree ; Seat member 50, 2 degrees; Ball valve 90 and the seat surface is 1 degree; Disc member 30, 2 degrees; Due to the structural limitations and functions of the outlet 21a at a predetermined working distance There was a problem that the flow rate is not smoothly adjusted, the valve according to the present invention is provided with the shape memory expansion spring 140 in the inner space portion of the support tube 130c of the valve disk 130 to act as a valve Since the tapered compression spring 150 is provided in the space portion between the outer peripheral surface of the support pipe 130c and the valve chamber 110, The length of the valve may be shortened, and the tapered disk 100a formed on the inner surface of the valve chamber 110 of the valve body 100 and the valve surface 130a formed in the tapered shape of the valve disc 130. It is characterized by the fact that the flow rate is finely adjusted according to the change of the interval within the predetermined working distance and the flow of the fluid is stabilized so that no noise occurs.

The working state according to the present invention will be described in detail with reference to Figs. 5a to 5b.

In the present embodiment, when the shape memory expansion spring 140 is in contact with the set minimum temperature, for example, 42 ℃ heating water is started to stretch, when the maximum temperature is 45 ℃ or more is fully elongated in the stored form. Therefore, the shape memory expansion spring 140 is elongated in a memorized form to maintain maximum inflation force when contacted with heating water having a temperature of 45 ° C. or higher, and when contacted with heating water having a temperature of 45 ° C. or lower. The expansion force of the shape memory expansion spring 140 is gradually reduced and the expansion force is at a minimum 42 ° C or less.

As shown in FIG. 5A and the embodiment, when the user has a temperature of 42 ° C. or lower, the expansion force of the shape memory expansion spring 140 is supported by the spring support end 130d of the valve disc 130 and compressed. The inner end of the valve face 130a of the valve disc 130 stops in contact with the end of the guide tube 120a of the valve guide 120 by being contracted by being much smaller than the elastic force of the tapered compression spring 150. When the temperature rises while the heating water is heated to a constant temperature in the boiler and reaches a maximum temperature of 45 ° C. or more, the expansion force of the shape memory expansion spring 140 becomes the maximum and is much larger than the elastic force of the tapered compression spring 150. As shown in FIG. 5B, the valve disc 130 is moved to be completely in contact with the disc seat 100a of the valve body 100 to be in a sealed state. The number of stops flowing heating.

At this time, when the temperature of the heating water is changed within the range of 42 ℃ and 45 ℃, the expansion force of the shape memory expansion spring 140 also changes in proportion, the opening and closing amount of the valve is increased and decreased, the flow amount of the heating water Since it is variable, it has the characteristic of temperature-sensing proportional control as illustrated in the flow characteristic diagram of the present invention of 4b degrees.

Referring to the embodiment of Figure 6 with reference to the embodiment as follows.

Even if hot water heated in the heat source equipment of the boiler 610 is equally provided to the heating coil pipe 640 in a room for each heating section (R₁, R₂, R₃, R₄) in which a conventional ball valve is installed, the degree of warming of the room is provided. It depends on the distance to the room, the area of the room, the length of the heating coil, and the state of heat insulation and heat dissipation.

Therefore, the heating time and the room temperature of the room are not uniform unless the valve 621 of the supply unit 620 is adjusted.

However, in the case where the thermostatic taper valve according to the present invention is installed and used in the return portion of the hot water distributor, the room is small and close to the hot water distributors (620, 630), for example, the room (R₁) and the room (R₂) are the first. When heated and the return temperature rises above 42 ℃, the valve is operated so that the temperature of the room is kept constant by varying the flow rate according to the return temperature.

The medium room (R₃) is warmed later than the room (R₁) and room (R₂), and the valve operates when the return temperature rises above 42 ° C. It is maintained.

In addition, the room is wider and the room (R₄) farthest from the hot water distributors (620,630) is warmed later than room (R₁), room (R₂), room (R₃), but is warmed first to keep room temperature constant. R₁), room (R₂), room (R₃) decreases the flow rate to room (R₄), so the heating time is faster, and then heating (R₁), room (R₂), room ( R₃), room (R₄) detects the water temperature to be returned and automatically adjusts the flow rate and maintains a constant temperature in the room, resulting in comfortable heating.

1 is a cross-sectional view of the automatic temperature control valve disclosed in Patent Publication No. 10-0742656

2 is a cross-sectional view of the heating water flow control valve disclosed in the registered Patent Publication No. 10-0779516

3 is a cross-sectional view of a thermostatic taper valve according to the present invention.

Figure 4a is a flow characteristic chart of the prior art

4b is a flow rate characteristic diagram of the present invention.

Figure 5a is a cross-sectional view of the fully-shrink open state for explaining the operating state according to the present invention

Figure 5b is a cross-sectional view of the fully expanded closed state for explaining the operating state according to the present invention

6 is a conceptual diagram schematically showing a boiler and a heating hot water supply system in a modern ondol house as an embodiment of the present invention.

Claims (3)

Inlet 110a and outlet 110b are formed in the valve chamber 110 having a predetermined size in order to flow the fluid from one direction to the other, and the valve chamber 110 on the inlet 110a side A tapered disc seat 100a having a predetermined angle and a spring hook end 100b are formed, and grooves 100c and 100d of the hole stop ring are formed on the inner circumferential surface of the valve chamber 110 toward the outlet 110b. And the valve body 100 characterized in that formed; By stop rings 160a and 160b between one side of the stop ring 160a fitted in the grooves 100c and 100d of the hole stop ring for the valve body 100 and one side of the stop ring 160b. A flange 120b is formed to be supported, and a valve guide 120 is formed at a central portion of one side of the flange 120b by a cylindrical guide tube 120a; A disk shaft (130b) is fitted to the inner circumferential surface of the guide pipe (120a) of the valve guide 120, and one end of the valve surface (130a) is formed with a cylindrical support tube (130c) in the longitudinal direction And valve disk 130; A shape memory expansion spring (140) inserted into an outer circumferential surface space of the guide tube (120a) of the valve guide (120); Thermostatic taper valve comprising a tapered compression spring 150 that is fitted to the outer peripheral surface space portion of the support tube 130c of the valve disc 130 The method according to claim 1 The surface of the flange (120b) in contact with the guide pipe (120a) of the valve guide 120 is formed with a plurality of holes through the hole 120d, the inner and outer peripheral surface of the cylindrical guide pipe (120a) is passed through a plurality of holes Thermostatic taper valve, characterized in that formed by (120c) The method according to claim 1 The valve surface 130a of the valve disk 130 is formed as a tapered disk, and the inner and outer circumferential surfaces of the cylindrical support tube 130c are penetrated to form a plurality of holes 130e. Thermostatic tapered valve characterized in that the end is formed by a spring support end (130d)

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