KR20100105111A - Heating automatic temperature control valve - Google Patents

Abstract

PURPOSE: An automatic temperature control valve for performing the heating is provided to dramatically reduce the total length of a valve by a tension bias spring installed in a coil spring. CONSTITUTION: An automatic temperature control valve for performing the heating comprises a valve body(410), an opening(420), a valve support(430), a disc(440), a coil spring(450) and a tension bias spring(460). The valve body comprises an inlet port(412), an outlet port(411) and a chamber(413). The opening is formed on the path of the chamber and comprises a protrusion(421) which is formed along the edge. The valve support is installed in the chamber. The disc makes contact with or is separated from the protrusion of the opening to open/close the chamber. The coil spring is installed between the disc and the valve support. If reaching the natural response temperature of shape memory alloy, the coil spring inflates and moves the disc toward the opening. Both ends of the tension bias spring are connected to the disc and the valve support. The tension bias spring supplies the elastic force in a direction in which the coil spring is contracted.

Description

Heating Automatic Temperature Control Valve {Heating Automatic Temperature Control Valve}

The present invention is a valve mainly installed in the return portion of the hot water distribution system connected to the heating boiler, by using the shape memory alloy automatically opens and closes the valve according to the temperature of the hot water to adjust the flow rate of hot water, thereby heating space It relates to a thermostatic valve in which the temperature of the gas is automatically adjusted.

A thermostat valve using a shape memory alloy has already been developed. In the case of the thermostat valve shown in FIG. 1 or 2, a valve chamber 203 is formed in which a fluid outlet 201a communicates with one side thereof. On the other side of the valve chamber 203, the valve body 201 is formed with a fluid inlet passage 201b penetrated in the longitudinal direction to communicate with it; A coil spring 204 embedded in the valve chamber 203 of the valve body 201 and made of a shape memory alloy to contract and expand as the temperature of the fluid moves up and down based on a set value; One side of the needle is fitted to the coil spring 204, and moves to the left and right in the valve chamber 203 of the valve body 201 according to the contraction and expansion of the coil spring 204 (opening and closing of the fluid passage) 205); A bias spring 206 whose one end is located on the inner side of the valve chamber 203 and the other end is fitted to the other side of the needle 205 to provide a force pushing the needle 205 to the open side of the valve chamber 203. ); A ball 207 installed in the fluid passage 201c of the valve body 201 to open and block the fluid passage 201b as it rotates in a predetermined angle direction; A ball stem 208 having one side connected to the ball 207 and the other side exposed to the outside of the valve body 201; A manual lever 209 coupled to the ball stem 208 to provide a rotational force to the ball 207; And a packing 210 provided on an outer circumferential surface of the ball 207 to maintain airtightness.

Such a valve structure may be used as a return valve provided in the heating facility, that is, for example, the return portion of the boiler.

In describing the operation of such a valve, when the low temperature fluid passes through the valve, the coil spring 204 is contracted, and the needle 205 fitted to the coil spring 204 is pulled toward the fluid inlet side. The fluid inlet 201b communicating with 203 is opened.

You will be released. At this time, the bias spring 206 pushes the needle 205 toward the fluid inlet side to facilitate the movement of the needle 205.

On the contrary, when a fluid having a high temperature higher than the set temperature of the coil spring 204 passes through the valve chamber 203 of the valve body 201, the coil spring 204 expands and thus the needle 205 is expanded. Valve chamber while overcoming pushing force of bias spring 206

Blocking the fluid outlet 201a of the 203 is to block the flow of the fluid.

As described above, the coil spring 204 automatically opens and closes the valve while the coil spring 204 contracts or expands according to the temperature of the fluid passing through the valve chamber 203 of the valve body 201 so that the fluid temperature is constantly maintained at a selected temperature. It is to be made.

When the fluid passage of the valve chamber 203 is artificially shut off, the fluid passage 201b of the valve body 201 is opened by rotating the lever 209 from the open position to the closed position. The ball 207 is rotated to block the fluid passage (201b)

will be.

However, although the temperature of the fluid is often changed by various environmental changes, the coil spring 203 is stretched only within its own temperature range. There was a problem that it is difficult to pass the fluid.

To solve this problem, as shown in FIG. 3, a shape memory alloy that varies according to temperature is mounted in the valve body to shield the valve when a fluid having a temperature higher than or equal to a set temperature flows. There is a thermostat valve that can adjust the opening and closing amount of the valve according to the temperature of the fluid required by the user to adjust the degree, the cam case 311 is installed inside the valve cover 302 and the cam case 311 The cam 312 is provided inside. In addition, the cam case 311 is connected to the valve stem support member 303 to move the valve stem 304 on which the disk 307 is mounted to the left or right in the drawing according to the rotation of the cam shaft 315. ) And the degree of opening and closing of the opening 301c by the disk 307 operated by the bias spring 310 can be arbitrarily adjusted.

However, such a complicated structure raises the unit cost of the product, and the coil spring 309 and the bias spring 310 are respectively installed on both sides of the disk 307, thereby increasing the overall length of the product.

Therefore, when the thermostatic valve is installed in a narrow space, the installation is restricted due to its length, which often causes great inconvenience in construction and design.

Accordingly, there is a need for a new concept of a thermostatic valve that can simplify the structure of the product and reduce the overall length, and can arbitrarily adjust the opening and closing amount of the valve.

It is an object of the present invention to simplify the structure and to reduce the overall length of the valve, and to provide a thermostatic valve capable of arbitrarily adjusting the opening and closing amount of the valve.

Technical composition of the present invention created to achieve the above object is as follows.

According to the present invention, an inlet 412 is provided at one end, and an outlet 411 is provided at the other end, and a valve body having a valve chamber 413 in an inner space between the inlet 412 and the outlet 411. 410; An opening 420 provided on a passage of the valve chamber 413; A valve support 430 fixed to the valve chamber 413; An opening / closing disk 440 which opens and closes the valve chamber 413 while being in close contact with or spaced from the opening 420; A coil spring 450 installed between the valve support 430 and the opening / closing disk 440 to expand and move the opening / closing disk 440 toward the opening 420 when the intrinsic sensitivity temperature is reached; And a tension bias spring 460 which is connected to both ends of the valve support 430 and the opening / closing disk 440 and positioned inside the coil spring 450.

Technical effects according to the present invention are as follows.

First, the manufacturing cost can be reduced by simplifying the structure of the thermostatic valve.

In other words, the cam case 311, the cam 312, the cam shaft 315 and the like shown in Figure 3 are not necessary, and the structure of the product itself is simplified, making it easier and easier to manufacture the product.

Secondly, unlike the conventional thermostatic valve, the tension bias spring 460 is installed inside the coil spring 450 of the shape memory alloy material, and the overall length of the valve can be significantly reduced.

In other words, in the case of the conventional thermostatic valve, the coil spring 309 and the (compression) bias spring 310 are installed to face each other on both sides of the disk 307, but the length of the valve itself is increased. In the case of the invention, unlike the related art, the tension bias spring 460 is installed inside the coil spring 450 to drastically reduce the length of the valve itself, thereby making it possible to manufacture a more compact thermostatic valve.

Third, by installing a separate disc-shaped disk 480 in the valve extending portion 470 it can be arbitrarily adjusted the opening and closing amount of the valve.

In other words, the disk-shaped disk 480 having a simple structure may be installed in the valve extension 470 to arbitrarily adjust the opening / closing amount of the valve.

Hereinafter, with reference to the accompanying drawings, a specific embodiment of the present invention will be described in more detail.

Figure 4 shows a configuration of a specific embodiment of the present invention, the valve support 430 is fixed to the inside of the valve body 410, the coil spring 450 made of a shape memory alloy, and the tension bias spring 460 One end of the structure is installed on the valve support 430, the other end of the coil spring 450 and the tension bias spring 460 is a structure for installing the opening and closing disk 440.

The valve body 410 is provided with an inlet 412 at one end and an outlet 411 at the other end, and a valve chamber 413 is provided in an inner space between the inlet 412 and the outlet 411.

That is, the hot water enters the inlet 412, passes through the valve chamber 413, and then exits the outlet 411.

An opening 420 having a step 421 is provided on the passage of the valve chamber 413, and the inlet 412 and the opening / closing disk 440 are in close contact with the step 421 formed around the opening 420. A passage connecting the outlet 411 is blocked.

As shown in FIG. 7, the valve support 430 is provided with a central piece 431 having a hollow 433 in the center portion thereof, and three support arms 432 extend from the central piece 431 to provide a valve body. The inner circumferential surface of 410 is reached. The support arm 432 may be provided with three or more in some cases, the space between the support arm 432 is a passage through which fluid flows.

The outer end of the support arm 432 is provided with a screw portion 11 is fixed to the valve chamber 413 in a manner that is fastened to the screw portion 12 provided on the inner peripheral surface of the valve body 410.

The opening / closing disk 440 serves to open or close the valve chamber 413 while being in close contact with or spaced from the step 421 of the opening 420.

That is, when the opening and closing disk 440 moves to the left side in the drawing, the opening 420 is gradually closed, and the flow of hot water flowing into the valve chamber 413 through the inlet 412 is gradually reduced, and the opening and closing disk 440. ) Close to the step 421 of the opening 420, the opening 420 is completely closed, and the flow of hot water is blocked.

The coil spring 450 is made of a shape memory alloy (SMA), which is installed between the valve support 430 and the opening / closing disk 440 as shown in FIG. 4, and has a unique response temperature of the shape memory alloy. When reaching, it expands to move the opening / closing disk 440 in the direction of the opening 420.

The coil spring 450 is made of titanium-nickel (Ti-Ni), which is excellent in durability. However, the coil spring 450 is not limited to only such a material, and may be expanded and contracted repeatedly according to the intrinsic response temperature. Any material can be used.

Both ends of the tension bias spring 460 are connected to the valve support 430 and the opening / closing disk 440, respectively, and are positioned inside the coil spring 450 so that an elastic force is applied in the direction in which the coil spring 450 contracts. .

As shown in Figure 4, one end of the tension bias spring 460 is coupled to a spring hook 441 provided on the rear surface of the opening and closing disk 440, the other end of the tension bias spring 460 is a valve support After passing through the hollow 433 of 430, the hollow 433 is coupled to the locking pin 434 supported by the central piece 431.

As such, when the valve support 430 and the opening / closing disk 440 are connected to one through the tension bias spring 460 inserted into the coil spring 450, the coil spring 450 is also opened and closed as shown in FIG. 4. It is positioned between the disk 440 and the valve support 430, the tension bias spring 460 is applied to the elastic force in the direction that the coil spring 450 is contracted so that both ends of the coil spring 450 opening and closing disk 440 and the valve support 430 is maintained in close contact.

In this state, when the temperature of the hot water passing through the valve chamber 413 reaches the intrinsic sensitivity temperature of the coil spring 450, the coil spring 450 expands and gradually closes the opening 420, thereby decreasing the flow rate of the hot water. On the contrary, when the temperature of the hot water falls below the intrinsic sensitivity temperature, the expanded coil spring is contracted to its original shape, and the opening / closing disk 440 moves to the right in the drawing by the elastic force of the tension bias spring 460, and the opening 420 is opened. Gradually open up.

Therefore, even if a separate temperature sensing device is not provided, the flow rate of the hot water passing through the valve chamber 413 is automatically adjusted to allow heating to an appropriate temperature.

5 and 6, the valve extension part 470, the cam housing 480, the opening and closing rotary shaft 490, and the rotary knob 491 is an embodiment further provided.

The valve extension part 470 is screwed with one end of the valve body 410, and a passage 471 communicating with the valve chamber 413 is provided therein.

Cam housing 480 is integrally fixed to the valve support 430 and the cam is built.

The inner end of the opening / closing rotary shaft 490 is connected to the cam of the cam housing 480 through the valve extending portion 470, and the outer end of the cam housing 480 protrudes outward from the valve extending portion 470. A rotation knob 491 for rotating the cam is attached.

When the rotary knob 491 is rotated, the cam housing 480 moves left and right according to the rotation of the cam, so that the valve support 430 and the opening / closing disk 440 move left and right together.

Therefore, the flow rate of hot water can be arbitrarily controlled separately from the opening and closing disk 440 which is automatically operated by the coil spring 450 and the tension bias spring 460.

That is, if you want to block or minimize the flow of hot water irrespective of the temperature of the hot water, as shown in FIG. 6, the rotary knob 491 may be turned to move in the direction in which the opening / closing disk 440 is closed. When the rotary knob 491 is rotated in the opening direction as shown in FIG. 5, the flow rate of the hot water is adjusted according to the temperature within a range where a certain amount of hot water flow is secured regardless of the temperature of the hot water.

That is, the range in which the flow rate of hot water is adjusted can be selected suitably.

As described above, the technical spirit of the present invention has been described with reference to specific embodiments of the present invention, but the protection scope of the present invention is not necessarily limited to these embodiments, and the scope of the present invention is not changed. Various design changes, additions or deletions of well-known technology, switching of conventional means, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

Figure 1 is an embodiment of a conventional thermostatic valve, showing a state in which the valve is open.

Figure 2 is an embodiment of a conventional thermostatic valve, showing a closed state of the valve.

3 is another embodiment of a conventional thermostatic valve, in which the opening and closing amount of the valve can be arbitrarily adjusted using a cam.

4 shows a configuration of a specific embodiment of the present invention.

FIG. 5 illustrates another embodiment of the present invention in which the valve extension 470 and the disc-shaped disc 480 are added, and the disc-shaped disc 480 completely blocks the passage 471 of the valve extension 470. One state is shown.

FIG. 6 shows a state where the disc-shaped disc 480 of FIG. 5 is opened as much as possible.

FIG. 7 shows a state in which the disk-shaped disk 480 of FIG. 5 is opened halfway.

<Description of the symbols for the main parts of the drawings>

410: valve body

411: outlet

412: inlet

413: valve chamber

420: opening

421: step

430: valve support

431: center

432; support arm

433: Hollow

434: locking pin

440: opening and closing disc

441: spring hanger

450: coil spring

460: tension bias spring

470: valve extension

471: passage

480: Cam Housing

490: rotary shaft for opening and closing

491: rotary knob

11, 12: screw part

Claims (4)

The inlet 412 is provided at one end and the outlet 411 is provided at the other end, the valve body 410 is provided with a valve chamber 413 in the inner space between the inlet 412 and the outlet 411. ; An opening 420 provided on a passage of the valve chamber 413 and having a step 421 formed along a circumference thereof; A valve support 430 installed in the valve chamber 413; An opening / closing disk 440 which opens and closes the valve chamber 413 while being in close contact with or spaced from the step 421 of the opening 420; Coil spring is installed between the valve support 430 and the opening and closing disk 440 and expands when the intrinsic response temperature of the shape memory alloy is reached to move the opening and closing disk 440 toward the opening 420. 450); And, Both ends of the valve support 430 and the opening / closing disk 440 are connected to each other, and are positioned inside the coil spring 450 to have a tension bias spring in which elastic force is applied in a direction in which the coil spring 450 contracts. 460); Thermostatic valve for heating, characterized in that configured to include. The inlet 412 is provided at one end and the outlet 411 is provided at the other end, the valve body 410 is provided with a valve chamber 413 in the inner space between the inlet 412 and the outlet 411. ; An opening 420 provided on a passage of the valve chamber 413 and having a step 421 formed along a circumference thereof; A valve support 430 installed to be slidable inside the valve chamber 413; An opening / closing disk 440 which opens and closes the valve chamber 413 while being in close contact with or spaced from the step 421 of the opening 420; Coil spring is installed between the valve support 430 and the opening and closing disk 440 and expands when the intrinsic response temperature of the shape memory alloy is reached to move the opening and closing disk 440 toward the opening 420. 450); Both ends of the valve support 430 and the opening / closing disk 440 are connected to each other, and are positioned inside the coil spring 450 to have a tension bias spring in which elastic force is applied in a direction in which the coil spring 450 contracts. 460); And, A valve extension part 470 provided with a passage 471 of a circular cross section which is screwed with one end of the valve body 410 and communicates with the valve chamber 413; A cam housing 480 integrally fixed to the valve support 430 and having a cam built therein; And, An inner end portion penetrates through the valve extension part 470 and is connected to the cam of the cam housing 480, and an outer end portion projecting outwardly of the valve extension part 470 rotates the cam of the cam housing 480. Opening and closing rotary shaft 490 to which the rotary knob 491 is attached; Further comprising, in accordance with the rotation of the rotary knob 491, the valve support 430 and the opening and closing disk 440, the automatic temperature control valve for heating, characterized in that to move left and right together. The method of claim 1 or 2, The valve support 430 is a central piece 431; And, A plurality of support arms 432 extending from the central piece 431; It is configured to include, The outer end of the support arm 432 is provided with a screw portion 11 is a thermostatic valve for heating, characterized in that fastened to the screw portion 12 provided on the inner peripheral surface of the valve body (410). 4. The method of claim 3, The center piece 431 of the valve support 430 is provided with a hollow 433, One end of the tension bias spring 460 is coupled to a spring hook 441 provided on the rear surface of the opening / closing disk 440, and the other end of the tension bias spring 460 opens the hollow 433. Thermostatic valve for heating, characterized in that coupled to the locking pin 434 supported by the center piece 431 across the hollow 433 after passing through.

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