JPH08114274A - Liquid break valve - Google Patents

Abstract

PURPOSE: To make any binding of a float in time of valve closing so as to be preventable as securing a sufficient flow rate at the time of setting internal pressure free by installing plural sets of floats, moving up and down together with a liquid level, and passage to be opened or closed by these floats. CONSTITUTION: When a liquid is poured into a tank, air in this tank is getting away into a vent line 20 by way of a hole 26 of a cap 4 and two passages 18a and 36a. Since both these passages are opened, an exhaust area of the air in the tank is sufficiently secured. Supposing the tank comes close to being fullness, the liquid gets into a valve body 2, and a main float 6 and a sub-float 34 both go up by dint of buoyancy, closing both the passages 18a and 36a. When a liquid level goes down due to liquid consumption, first of all, the main float 6, where a hole diameter of the passage 18a is small and a pressure differential between both fload upper and lower surfaces is also small, goes down without entailing any binding to a valve seat 18, so the passage 18a is opened. In consequence, a pressure differential between both upper and lower surfaces of the sub-float 34, so the passage 36a being large in a valve hole diameter is opened, returning to a normal condition.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used, for example, in a fuel tank of an automobile or the like, and in a normal state, the pressure generated inside the fuel tank or the like (because the fuel vaporizes if the liquid to be stored is fuel). (The vapor pressure becomes the internal pressure) is released to the outside, and the fuel tank etc. is shaken when the automobile runs.
The present invention relates to a liquid cutoff valve that closes when tilted or falls and shuts off the outflow of stored liquid.

[0002]

2. Description of the Related Art As a conventional liquid cutoff valve having a float, for example, those shown in FIGS. 7 and 8 are known. That is, 102 is a hollow valve body, 104 is a cap incorporated in the lower portion of the valve body 102, and 106 is a float that is vertically movable in an internal space created by the valve body 102 and the cap 104. Reference numeral 108 denotes a spring, which biases the float 106 upward with a spring force weaker than the weight of the float 106.

A valve seat 118 is provided at the center of the upper surface of the inside of the valve body 102, and connects the inside of the valve body 102 to the outside via a ventilation pipe 120. In addition, a protrusion-shaped valve portion 122 is provided at the center of the upper surface of the float 106.
Therefore, the valve is formed together with the valve seat 118, and the valve is opened and closed by the vertical movement of the float 106. A plurality of vertical grooves 124 are provided on the side surface of the float 106, which communicates the spaces above and below the float 106, and allows liquids, vapors, and the like to freely flow in and out. Further, there is a hole 126 in the center of the cap 104 to connect the inside of the fuel tank or the like to the inside of the valve body 102.

[0004]

However, in the liquid cutoff valve of the type having the float 106, the valve portion 122 of the float 106 has the valve seat 118 due to the buoyancy of the liquid such as fuel contained in the fuel tank or the like. Even if the liquid level drops after seated on the valve seat, the valve portion 122 of the float 106 may be closed due to the pressure difference between the inside and the outside of the fuel tank.
There was a case where it stuck to and could not be separated.

In order to solve this, it is conceivable to increase the weight of the float 106. However, since the force for lifting the float 106 upward is reduced by the increased weight, when the fuel tank or the like is shaken or tilted. Etc., the responsiveness is deteriorated, and liquid such as fuel leaks more.

If the cross-sectional area of the passage opened in the valve seat 118 is made small and the pressure acting on the float 106 is made small, the float 106 easily falls. However, since the gas flow rate through the passage is reduced, the ability to release the internal pressure of the tank is reduced. As a result, the internal pressure of the tank increases, and in extreme cases, the tank may be deformed.

The present invention has been made to solve the above-mentioned problems of the prior art, and its purpose is to ensure a sufficient flow rate when the internal pressure is released without impairing the responsiveness of the float. At the same time, another object of the present invention is to provide a liquid cutoff valve capable of preventing the float from sticking when the valve is closed.

[0008]

In order to achieve the above object, according to the present invention, an internal hollow valve body is provided above a tank for storing a liquid, and the valve body is inserted into the hollow interior of the valve body. A float that moves up and down together with the liquid level of the liquid flowing into the valve body, and a passage that connects the inside and the outside of the tank opening at the top of the valve body and is opened and closed by the float,
In the liquid cutoff valve provided with, a plurality of sets of the float and the passage are provided.

Further, the seal area of the float when at least one of the plurality of floats and the passage is closed is smaller than the seal area of the other float when the other passage is closed. To do.

[0010]

In the above liquid shutoff valve, in a normal state where the liquid level in the tank is lowered, buoyancy is not acting on the plurality of floats, so the floats are lowered by their own weight. is open. When the liquid is injected into the tank in this state, the gas volume of the tank is narrowed by the rise of the liquid level, the tank internal pressure rises, and the gas pressure escapes to the outside through the plurality of passages. Since the plurality of passages are open, the exhaust area of the gas in the tank is sufficiently secured.

When approaching the full tank state, the liquid enters the inside of the valve main body, lifts the plurality of floats by buoyancy, and closes the passage opened to the upper part of the valve main body by the floats.

When the liquid surface is lowered due to the consumption of the liquid, the buoyancy is lost and the float falls downward by its own weight. Here, if the pressure difference between the gas acting on the upper and lower surfaces of the float is small, the upward force for fixing the float is weakened, and the float is likely to fall.

In the present invention, since a plurality of passages are provided, if the passage cross-sectional area of the passage is sufficient to ensure the outflow, the passage cross-sectional area is smaller than that of one passage. It can be small. If the flow passage cross-sectional area is reduced, the sealing area for closing the passage by each float is also reduced, and the force acting on the float in the valve closing direction is also reduced, so that the float is easy to open.

In particular, by making the sealing area of the float when closing at least one passage smaller than the sealing area of the other float when closing other passages, the smaller sealing area opens first. The tank pressure has dropped,
Then, the float having the larger sealing area is opened to return to the normal state.

The same applies when the tank is shaken or tilted due to transportation or the like, and when the tank is inverted by 180 degrees (falling down), a plurality of floats are pushed up by buoyancy simultaneously with the rise of the liquid level, and the floats react quickly. Then, the passage is closed to stop the liquid outflow. The internal pressure in the tank can escape from a plurality of passages having a sufficient flow passage cross-sectional area even if the liquid surface is expelled due to a rapid rise.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the illustrated embodiments.

In FIG. 1 showing a liquid cutoff valve according to the present invention, reference numeral 2 is a hollow internal valve body having an open lower end, and 4 is a cap incorporated in the lower end opening of the valve body 2. The valve body 2 and the cap 4 form a hollow internal valve body, and the main float 6 is vertically movable in an internal space created by the valve body 2 and the cap 4.

The main float 6 is provided with a cylindrical hole 32 vertically extending from the upper surface to an intermediate height apart from the center, and another small sub-float 34 is provided in the hole 32.
The main float 6 is fitted in a vertically movable manner. 8
Is a spring that biases the main float 6 upward with a spring force that is weaker than the weight of the main float 6.

A flange 10 for fixing is provided on the upper outer side of the valve body 2, and the flange 10 has a plurality of screw holes 1.
There are two. Covering the flange 10 is a fixing cover 14, and below the flange 10 is a packing 16. The liquid cutoff valve is attached, for example, by inserting the valve body 2 into a hole provided in an upper portion of a fuel tank or the like from above, and the cover 14, the flange 10 and the packing 16 are screwed to the upper portion of the fuel tank or the like. It is stopped and fixed so that liquid such as fuel inside does not leak.

A valve seat 18 for the main float 6 is provided at the center of the upper surface of the valve body 2, and a ventilation pipe 20 is provided.
Also, the inside of the valve body 2 is communicated with the outside through a passage 18a that opens to the valve seat 18. Furthermore, the inner upper surface of the valve body 2 is offset from the center,
There is another valve seat 36 for the sub-float 34, which communicates with the ventilation conduit 20 via a passage 36a.

The passage 18a of the valve seat 18 for the main float has a small passage sectional area, and the passage 36a of the valve seat 36 for the sub-float has a large passage sectional area.

Further, there is a protruding valve portion 22 at the center of the upper surface of the main float 6, and the passage 18a is opened and closed by the vertical movement of the main float 6. The top portion of the sub-float 34 is rounded up to form a valve portion 38, which moves up and down the main float 6 or the sub-float 34.
The passage 36a is opened and closed by the vertical movement of the.

The main float 6 is positioned with the valve body 2 by a guide mechanism (not shown) so that the position of the sub-float 34 always matches the valve seat 36.

The guide mechanism is composed of, for example, a plurality of vertical grooves 24 provided on the side surface of the main float 6 and a guide protrusion 25a engaging with the vertical groove 24 provided on the inner circumference of the valve body 2. . Further, on the outer circumference of the main float 6, a protrusion 25b engaging with the inner circumference of the valve body 2 is provided.
Are provided in the circumferential direction to prevent the main float 6 from rattling. Then, the liquid and gas on the upper and lower ends of the main float 6 freely flow in and out through the gaps between the protrusions 25b.

Also, the cylindrical hole 32 of the main float 6
Between the side surface of the sub-float and the sliding surface of the sub-float 34, a passage 35 that allows liquid and gas to freely move in and out is formed, and vertical movement of the sub-float 34 is not hindered.
Further, the sub-float 34 can receive sufficient buoyancy. It is not necessary to prevent the sub-float 34 from rotating, and in this embodiment, a plurality of projections 35 that abut the outer circumference of the sub-float are provided in the inner circumference of the hole 32 in the circumferential direction, and the gap between the projections 35 forms a passage. ing.

A hole 26 is formed in the center of the cap 4 so that the interior of the fuel tank or the like and the interior of the valve body 2 are communicated with each other.

The embodiment of the liquid cutoff valve according to the present invention constructed as described above operates as follows.

First, in a normal state in which the liquid level in the tank is lowered, both the main float 6 and the sub float 34 are
It is lowered because buoyancy is not acting, and the passages 18a and 36a are open.

In this state, when liquid is injected into the tank, such as refueling, the volume of the gas in the tank is reduced due to the rise of the liquid level and the pressure in the tank rises. It passes through the passages 18a and 36a and goes out to the ventilation pipe line 20. Since both of the two passages 18a and 36a are open, the exhaust area of the air in the tank is sufficiently secured.

When the state of fullness is approached, the liquid enters from the inside of the tank to the inside of the bob body 2, and the main float 6 and the sub-float 34 are lifted by the buoyancy and the passages 18a,
The passage 36a is closed.

When the liquid such as fuel is consumed and the liquid decreases from the full tank state, the liquid surface lowers and buoyancy is lost. At this time, first, the main float 6 having a small hole diameter of the passage 18a and a small pressure difference of the gas acting on the upper and lower surfaces of the float
However, it is lowered without sticking to the valve seat 18 and the passage 18a is opened.

As a result, the tank internal pressure is released to the ventilation pipe line 20 and lowered, and the pressure difference of the gas acting on the upper and lower surfaces of the sub-float 34 is lowered. Therefore, this time, even the sub-float 34 having a large valve hole diameter is lowered, the passage 36a is opened, and the normal state is restored.

Here, the principle of sticking prevention by reducing the seal diameter, that is, the cross-sectional area of the flow path is shown in FIG.
An explanation will be given based on (b).

The main float 6 is fixed to the passage 18a by fixing the seal diameter when the main float 6 is seated on the valve seat 18, d, the internal pressure of the tank, and the main float 6.
Assuming that the self-weight is W and the load of the spring 8 is Fs, (π / 4) · d ² · p> (W−Fs)
In a relationship.

To open the valve, (π / 4) · d^Two ・
It is necessary that p <(W-Fs). Let the valve opening pressure be p0
Then, p0 = (W−Fs) / (π / 4) · d^TwoNext to the car
Mainly unless p <p0 during tank rocking such as material rocking
The float does not open.

In order to increase p0, (W-Fs) may be increased, but the response is deteriorated and the liquid such as fuel during rocking increases in leakage. Therefore, in the present invention,
By reducing the seal diameter d without changing the size of (WFs), p0 is raised to prevent sticking.

In this normal state, when the tank shakes or tilts due to transportation or the like, the liquid level rises sharply, and at the same time, the main float 6 and the sub-float 3
4 tries to push up with 4 by buoyancy. The gas pressure in the tank can escape from the two valve holes that have sufficient area for ejection due to a sudden rise in the liquid level, and it does not interfere with the movement of the main float 6 and the sub-float 34. Absent. Therefore, the main float 6 and the sub-float 34 move quickly to close the valve and stop the outflow of liquid. As a result, fuel leakage does not occur even when reversing (falling over) 180 degrees.

Another embodiment of the present invention is shown in FIGS.
In these embodiments, the same components as those in the first embodiment are designated by the same reference numerals and the description thereof will be omitted.

The second embodiment of FIG. 3 is also the main float 72.
And the sub-float 74, and the two floats 72, 74 are different from the first embodiment only in the shape of the sub-float 74.
And one of the valve seats 78, 79
It is the same that the hole diameter of 8a is small and the hole diameter of the other passage 79a is large, and the operating principle thereof is also the same. Also in this embodiment, the main float 72 moves up and down in the valve body 76, and the sub float 74 moves up and down with respect to the main float 72.

In the third embodiment of FIG. 4, the main float 8
The relationship between 2 and the sub-float 84 is independent of each other.
Both floats move up and down independently in the valve body 86. However, it is the same that the passage 88a opening to one valve seat 88 has a small hole diameter and the passage 89a of the other valve seat 89 has a large hole diameter, and the operating principle thereof is also the same as that of the first embodiment.

The cross-sectional shape of the main float 82 and the sub-float 84 may be circular as shown in FIGS. 4 (b) and 4 (c), or may be radiused as shown in FIGS. 4 (d) and 4 (e). It may have a shape. 4B and 4D are cross sections in the A direction (float side) in FIG. 4A, and FIGS. 4C and 4E are cross sections in the B direction (valve seat side). .

FIG. 5 shows a fourth embodiment of the present invention.

This fourth embodiment also has a main float 406.
The sub-float 434 and the sub-float 434 are different from the first embodiment in that the shapes of the main float 406 and the sub-float 434 are different, and the relationship between the two floats and the valve seats 418, 4 are different.
Of the 36, it is the same that one of the passages 418a has a small hole diameter and the other passage 436a has a large hole diameter, and the operating principle thereof is also the same. Also in this embodiment, the main float 40
6 moves up and down in the valve body 402, and the sub-float 4
34 is configured to move up and down with respect to the main float 406.

The main float 406 has a hollow cylindrical shape with its upper end closed, and the valve portion 422 is provided at a position separated from the center of the upper end wall 403 by a predetermined distance. The back surface of the upper end wall 403 of the main float 406 and the valve body 402
The spring 408 interposed between the caps 404 that closes the lower end opening of the spring 408 is arranged corresponding to the position of the valve portion 422, and protrudes on the back surface of the upper end wall 403 so as to be inserted into the inner circumference of the spring 408. A cylindrical convex portion 409 is provided.

On the other hand, the sub-float 434 is eccentrically arranged on the side opposite to the valve portion 422 of the main float 406 and is vertically movably inserted into a hole 432 provided in the upper end wall 403 of the main float 406. . The sub-float 434 also has a hollow cylindrical shape with its upper end closed, and a valve portion 438 is formed at the center of the upper end wall 435 so as to project. Also,
A spring 437 is mounted between the back surface of the upper end wall 435 of the sub-float 434 and the bottom surface 433 of the hole 32, and a convex portion protruding on the back surface of the upper end wall 435 of the sub-float 434 so as to engage with the inner circumference of the upper end of the spring 437. 439 is provided. The spring 437 is also attached to the bottom surface 433 of the hole.
Is provided with a protruding portion 440 that projects so as to engage with the inner circumference of the lower end of the.

The guide mechanism of the main float 406 is the first
With the same configuration as that of the embodiment, as shown in FIG. 5B, a vertical groove 424 provided on the peripheral wall thereof and a guide projection provided on the inner circumference of the valve body 402 so as to engage with the vertical groove 424. With 425a, it guides in the vertical direction while trying to prevent rotation. Further, a plurality of protrusions 425b that engage with the peripheral wall of the main float 406 are provided on the inner circumference of the valve body 402 in the circumferential direction to prevent rattling of the main float 406, and a gap between the protrusions 425b is formed in the main float 4
A passage that connects the spaces on the upper and lower ends of 06 is formed.

Similarly to the first embodiment, the sub-float 434 is also guided by the projections 432a provided on the inner circumference of the hole 432, and the gap between the projections 432a constitutes a passage. In this embodiment, the hole 32 is the main float 40
6 is provided so as to be inscribed in the outer peripheral edge of No. 6, and is cut out at the inscribed position, and a part of the projection 432a provided on the inner periphery of the valve body 402 is formed around the sub-float 434 through the notch 432b. It is in contact with the surface.

Further, in this embodiment, the valve body 40
The upper end wall 401 of 2 has a recess 401 that opens upward.
a is provided, and the passages 418a and 436a of the valve seats 418 and 436 for the main float 406 and the sub float 434 are opened on the bottom surface 401b of the recess 401a. The recess 403a is formed on the side surface of the upper end wall 401.
A nipple 420 that constitutes a ventilation pipe communicating with is attached.

The other structure and operation are the same as those of the first embodiment, and the same components are designated by the same reference numerals and their description is omitted.

FIG. 5C shows a fifth embodiment of the present invention.

The fifth embodiment is basically the same as the fourth embodiment, except that the upper and lower ends of the springs 437 of the sub-float 434 and the convex surface of the upper wall 435 of the sub-float 434 are convex. Bottom 433 of portion 439 and hole 432.
It is in the point that it is press-fitted into and integrated with the convex portion 440 provided on the.

In this way, the main float 406
When is dropped, the sub-float 434 is pulled by the spring 437, and the sub-float 434 is easily dropped.

FIG. 6 shows a sixth embodiment of the present invention.

This sixth embodiment also has the same structure as the fourth embodiment, except that the hole 432 of the main float 406 is different.
A claw 441 is provided on the opening edge so as to engage with the upper end wall 435 of the sub float 434.

In this way, the main float 406
When the claws 441 fall, the claws 441 move the upper end wall 4 of the sub float 434.
The sub-float 434 is easily caught by the hook 35.

In the above embodiment, the hole diameters of the passages are related to each other, but the hole diameters may be the same. Even if the hole diameter is the same, compared to the case where a set of float and passage are used, the responsiveness of the float is not impaired, and a sufficient flow rate for releasing the internal pressure can be secured, and the float is fixed when the valve is closed. Can be prevented.

Although the structure having two sets of floats and the passages opened and closed by the floats has been illustrated, three or more floats and the passages opened and closed by the floats may be provided.

[0058]

As described above, according to the present invention,
Since a plurality of sets of floats and passages are provided, a plurality of passages are opened when the valve is opened, so that a sufficient discharge area of the gas in the tank can be secured.

Further, since a plurality of passages are provided, the passage cross-sectional area of the passage can be made smaller than that of one passage as long as the passage cross-sectional area of the passage can ensure the outflow. If the pressure is reduced, the sealing area for blocking the passage due to each float is also reduced, and the gas pressure acting on the float in the valve closing direction is also reduced to prevent the float from sticking.

In particular, if the seal area of the float when closing at least one passage is smaller than the seal area of the other float when closing other passages, the smaller seal area opens first and the tank opens. The internal pressure can be reduced and the float can be opened reliably.

The same applies when the tank is shaken or tilted due to transportation movement or the like, and when 180 degrees inversion (falling) is performed, a plurality of floats are pushed up by buoyancy simultaneously with the rise of the liquid level, and the floats react quickly. Then, the passage is closed to stop the liquid outflow. The internal pressure in the tank can escape from a plurality of passages having a sufficient flow passage cross-sectional area even if the liquid surface is expelled due to a rapid rise.

[Brief description of drawings]

FIG. 1 (a) is a front sectional view of a liquid cutoff valve according to a first embodiment of the present invention, and FIG. 1 (b) is an enlarged explanatory view of a seal portion.

2 is a plan view and a side view of two floats of the liquid shutoff valve of FIG. 1. FIG.

FIG. 3 is a front sectional view of a liquid cutoff valve according to a second embodiment of the present invention.

FIG. 4 is a diagram showing a liquid cutoff valve according to a third embodiment of the present invention.

5 (a) and 5 (b) are views showing a liquid cutoff valve according to a fourth embodiment of the present invention, and FIG. 5 (c) shows a liquid cutoff valve according to the fifth embodiment of the present invention. It is a figure.

FIG. 6 is a diagram showing a liquid cutoff valve according to a sixth embodiment of the present invention.

FIG. 7 is a front sectional view of a conventional liquid cutoff valve.

FIG. 8 is a partial view showing a closed state of the liquid cutoff valve of the conventional example of FIG. 7.

[Explanation of symbols]

 2 valve body 4 cap 6 main float 8 spring 10 flange 12 screw hole 14 cover 16 packing 18 valve seat 18a passage 20 ventilation pipe 22 valve part 24 vertical groove 25a guide protrusion 25b protrusion 26 hole 32 hole 34 sub-float 36 valve seat 36a Passage 38 Valve portion 72 Main float 74 Sub float 76 Valve body 78, 79 Valve seat 78a, 79a Passage 82 Main float 84 Sub float 86 Valve body 88 Valve seat 88a Passage 89 Valve seat 89a Passage 401 Upper end wall 401a Recess 401b Bottom 402 valve Body 403 Upper end wall 403a Recess 404 Cap 406 Main float 408 Spring 409 Convex 418 Valve seat 418a Passage 420 Trachea 422 Valve part 424 Vertical groove 425a Guide projection 425b Projection 432 Hole 432a Projection 432b Cutout part 433 Bottom surface 434 Subfloat 435 Upper end wall 436 Valve seat 436a Passage 437 Claw part 439 Convex part 44 438 Valve part 439

Claims (2)

[Claims] 1. A valve body having an internal hollow disposed above a tank for storing a liquid, and a float that is inserted into the hollow inside of the valve body and moves up and down together with the liquid level of the liquid flowing into the valve body.
A liquid cutoff valve comprising: a passage that communicates with an inside and an outside of a tank that opens at an upper portion of the valve body and that is opened and closed by the float, wherein a plurality of sets of the float and the passage are provided. . 2. A seal area of the float when at least one of the plurality of floats and passages is closed is smaller than a seal area of the other float when other passages are closed. The liquid cutoff valve according to claim 1.