JPH02302627A - Remaining-quantity annunciator of liquified gas container - Google Patents

Abstract

PURPOSE:To report the remaining quantity of liquified gas automatically by providing a constitution wherein a switch means is operated when a float is exposed from the liquified gas and a warning means in made to be an operating state. CONSTITUTION:A remaining-quantity annunciator 20 has an approximately cylindrical main body 21 which can be attached to a liquified gas container. The reporting device 20 is attached to the liquified gas container with an engaging part 22 and a screw part 23. When the liquified gas is decreased and the liquid surface is decreased lower than a float 29, bouyancy owing to the float 29 is reduced. A shaft 28 and a magnet 31 are lowered and reach the lower limit position. Then, a magnet switch 32 is switched, and the ON state is obtained. Thus warning is issued from a warning device. In this way, the fact that the remaining quantity of the liquified gas has reached the limit can be reported.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a remaining amount indicator for notifying the remaining amount of a container containing liquefied gas such as liquid oxygen.

[Conventional technology]

BACKGROUND ART Various devices have been known to notify the remaining amount of a liquefied gas container.

For example, in liquefied gas containers used for home oxygen therapy using liquid oxygen, the remaining amount is displayed by the weight of the liquid oxygen using a platform scale, and the pressure at the bottom of the container is lower than that of the gas at the top of the container. A ``differential pressure type liquid level gauge'' is known that takes advantage of the fact that the pressure at a certain point is higher than the weight of the liquefied gas, and converts the pressure difference between the two into the amount of liquefied gas and displays it.

Among industrial liquid level gauges, a "float type level gauge" that uses a float to display the liquid level is known. An example of this "float type liquid level gauge" will be explained with reference to FIG.

In Figure 4, (1) is the liquefied gas container, and the outer tank (2)
and an inner tank (3), and the space (4) between the two tanks (2) and (3) is kept under vacuum. The upper opening of the liquefied gas container (1) is sealed by a lid (5), and this lid (5) has a pipe (6) for supplying and discharging the liquefied gas and a pipe (7) for discharging the gas.
A gauge tube (8) with a transparent scale is attached. Inside the inner tank (3), a rod-shaped float (10) made of light metal and having a display piece (9) attached to its upper end is provided in the vertical direction. This flow (10) is made of a low-temperature resistant metal that can withstand the temperature of liquefied gas, and is lifted by a reinforcing spring (11) with one end fixed to the gauge tube (8) to compensate for the lack of buoyancy. It is. Further, the float (10) extends over almost the entire length of the inner tank (3) as shown. Note that (12) is the liquid level of the liquefied gas.

When the liquid level (12) in the liquefied gas container (1) changes, the float (10) moves up and down due to the difference in specific gravity between the liquefied gas and the float (10). ) allows you to check the remaining amount by visually observing it from the outside.

In addition, in order to make this liquid level gauge compact, the liquid level (
12) Flow even if there are large fluctuations! - The buoyancy must be adjusted so that the amount of movement (10) is small.

The float (10) used in this type of level gauge does not have a hollow body, which is advantageous in terms of buoyancy, but has a closed internal structure for the following reasons.

For example, in the case of liquid oxygen, when liquid oxygen exists in the container, the temperature becomes -180 C1 and when it does not exist, the temperature becomes room temperature, so the temperature difference around the float (10) is 200'
There is a grade of C. For this reason, unless the hollow part of the flow (10) is made a vacuum, the gas inside the hollow part will repeatedly expand and contract, so the structure must be able to withstand this, but achieving this is due to technical aspects. This is because it is extremely difficult both in terms of cost.

Additionally, if the airtightness of the hollow part is incomplete, liquefied gas may enter the hollow part due to a drop in atmospheric pressure.If the float (lO) is returned to room temperature in this state, the liquefied gas inside will expand rapidly ( This is because liquid oxygen expands approximately 800 times) and is extremely dangerous.

[Problem to be solved by the invention]

In this way, the float-type liquid level gauge described above
(10) In order to display the change in buoyancy caused by the change in the amount of the part immersed in the liquefied gas as the remaining amount of liquefied gas, the float (10) that senses the remaining amount must be shaped like a long rod. At least the inner tank (
3) A length corresponding to the height of the liquid level when full is required from the bottom, and all portions that come into contact with the liquefied gas must be of the same diameter and homogeneous.

In addition, although conventional liquid level gauges can tell the change in the remaining amount of liquefied gas over time, the user must confirm that the remaining amount has reached a predetermined level. There is a risk of it being stored away.

The present invention has been made in view of the above-mentioned conventional circumstances, and its purpose is to automatically notify that the remaining amount of liquefied gas has reached a predetermined amount, and to provide a portion that detects the remaining amount of liquefied gas. It is an object of the present invention to provide a remaining amount indicator for a liquefied gas container whose configuration can be simplified.

Another object of the present invention is to provide a remaining amount alarm for a liquefied gas container that can accurately issue an alarm without applying unreasonable force to the remaining amount sensing portion of the liquefied gas even if the container is tilted. It is.

[Means to solve the problem]

In order to achieve the above object, the present invention takes the following technical measures.

That is, a main body attached to the liquefied gas container; a shaft provided in the main body so as to be movable up and down and housed in the liquefied gas container; a float attached near the lower end of the shaft; The apparatus further includes a switch means that is switched by the movement of the shaft, and an alarm means provided outside the liquefied gas container that is activated by the switch means, and when the float is exposed from the liquefied gas, the switch means is activated. , characterized in that the alarm means is configured to be activated.

The invention also includes a connecting member having a concave spherical part fixed to the main body, and a cylindrical body having a spherical part slidably held by the concave spherical part, and the shaft is attached to the cylindrical body so as to be movable up and down. is preferable.

[Effect]

With the above structure, when the shaft is inserted into the liquefied gas container and the main body is attached to the liquefied gas container, the entire float is immersed in the liquefied gas and located near the bottom of the float. The position of the float is set according to the remaining amount of liquefied gas that should issue an alarm.

When the use of liquefied gas is started, the buoyancy hardly changes while the float is submerged in the liquefied gas, the switch means provided on the main body remains in its original state, and no alarm is issued.

As the amount of liquefied gas decreases and a portion of the float becomes exposed, the buoyant force decreases and the float and shaft descend. This movement switches the switch means and activates the alarm means.

In this way, the remaining amount of liquefied gas can be automatically notified.

〔Example〕

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIGS. 1 and 2 show an embodiment of a remaining amount indicator for a liquefied gas container according to the present invention. This remaining amount indicator (2
0) has a substantially cylindrical main body (21) that can be attached to a liquefied gas container, and the upper half of this main body (21) has a substantially hexagonal storage structure for engaging a spanner, etc. Joint (22
), and the lower half is a threaded portion (23) for screwing into the opening of the liquid container.

A hollow chamber (23a) is provided inside the threaded portion (23), and a connecting member, that is, a connecting nut (24) is screwed into the opening. The connecting nut (24) is provided with a concave spherical surface (24a) and a tapered portion (24b) as shown in FIG. It is held in slidable contact with the portion (24a). Therefore, the flexible sleeve (25) is swingable around the spherical portion (25a).

(28) is a shaft, the upper end of which passes through the center hole (25b) of the flexible sleeve (25) and extends through the cavity (2) of the threaded portion (23).
3a), and a float (29) is fixed near the lower end. A magnet (31) is fixed to the upper end of the shaft (28), and moves up and down within the empty chamber (23a) as the shaft (28) moves up and down. Even if the shaft (28) is located at the lowest position, it will not come off from the flexible sleeve (25) due to the locking body (not shown). Moreover, the shaft (28) is formed thinly,
This greatly reduces the effect of buoyancy.

The shape of the float (29) is not an elongated bar shape like that of a conventional liquid level gauge, but a round bar shape that is considerably thicker than the shaft (28) and has a solid shape. An annular recess (30) for setting the liquid level at which the alarm (20) operates is formed approximately in the center of the flow (29).

Further, the shaft (28) is suspended by a reinforcing spring (26) whose upper end is fixed to the flexible sleeve (25) in order to reinforce the buoyancy of the float (29). The lower end of the reinforcing spring (26) is attached to the shaft (
28).

The shaft (28), float (29), and reinforcing spring (26) described above constitute a remaining amount sensing section of liquefied gas.

The retaining part (22) of the main body (21) has the above-mentioned empty chamber (
A space (22a) is provided which is separated from 23a) by a partition wall, and the magnet (3) is placed in this space (22a).
1) is operated by a magnetic switch (3).
2) is provided. The upper opening of the cavity (22a) is closed with a filler (33), thus sealing and protecting the magnetic switch (32).

The lead wire (34) of the magnet switch (32) is connected to the alarm (36) via the connector (35) outside the liquefied gas container.
), and an alarm (36) issues an alarm in response to the operation of the magnetic switch (32) to notify the remaining amount. Note that (38) is a lead wire for the alarm (36), and (38) is a power outlet.

A packing (50) is provided on the outer periphery of the threaded portion (23).

Next, the usage status of the remaining amount indicator (20) configured as above will be explained.

In Fig. 3 (a) and (b), (39) is a conventionally known liquefied gas container, consisting of an outer tank (42) and an inner tank (43), with a gap between the two tanks (42) and (43). The space (44) is evacuated. The liquefied gas is contained in an inner tank (43). (40) is a lid that closes the opening of the liquefied gas container (39), and the main body (21) of the remaining amount indicator (20) is screwed into the through hole provided in the center of the lid.
) is immersed in the internal liquefied gas (41). The float (29) is located near the bottom of the inner tank (43). The space between the main body (21) and the lid (40) is sealed by a gasket (50).

The main body (21) of the remaining amount indicator (20) has an empty chamber (23a) that communicates with the inner tank (43) and an empty chamber (22a) that communicates with the outside that are separated by a partition wall. The through hole of M (40) is sealed.

In addition, (45) is a pipe for supplying and discharging liquefied gas, (46) is a pipe for gas discharge, (47) and (48) are both the above-mentioned pipes (45).
A stop valve is attached to (46), (49) is a pipe (46)
) is a safety valve attached to the

As shown in FIG. 3(a), when the liquefied gas is full, the float (29) has its own buoyancy and the reinforcing spring (2
6) is pulled upward by the elastic force and is at the upper limit position,
The magnet (31) is in contact with the earthen wall of the vacant room (23a). In this state, the magnetic switch (32) is
Since it is in the FF state, the alarm (36) does not operate.

Even if liquefied gas is used and the liquid level (41) falls, the force pushing up the shaft (28) will hardly change until a part of the float (29) is exposed from the liquefied gas, so the magnetic switch (32) ) remains OFF.

In this embodiment, the shaft (28) is made thinner than the float used in conventional float-type liquid level gauges, while the diameter of the float (29) is made larger than the shaft (28). The shaft (28
This is because the buoyancy hardly changes depending on the change in the length of the flow (29), but changes greatly depending on the amount of exposure from the liquefied gas in the flow (29).

As the liquefied gas decreases, the liquid level (41
) becomes lower than float (28), float (29
) decreases, and the shaft (28) and magnen (31) descend to reach the lower limit position. Then, the magnetic switch (32) is switched to the ON state, and the alarm (36) is activated to issue an alarm.

In this way, it is possible to notify that the remaining amount of liquefied gas has reached its limit.

Even if the liquefied gas container (39) is not placed on a flat surface but on a surface that is somewhat inclined from the horizontal surface, the above operation is performed smoothly and no problem occurs. In this invention, the shaft (28) supporting the float (29) is connected to the flexible sleeve (
25), the sleeve (25) can swing around the spherical portion (25a). Also liquefied gas container (39)
Even if the shaft (28) swings during transportation, the shaft (28) swings accordingly, so that no stress due to bending or twisting is applied to the shaft (28).

As the alarm device (36), any publicly known alarm device may be used as appropriate, but in order to increase the reliability of the notification, it is preferable to use a lamp or the like to provide a visual appeal as well as a buzzer or the like to provide an auditory appeal. .

Further, as a switch means, in this embodiment, a magnetic switch (32) is used to operate with a magnet (31), but the present invention is not limited to this, and any other arbitrary switch can be used. Of course, it can be used.

〔Effect of the invention〕

As is clear from the above description, the remaining amount indicator (20) according to the present invention detects a drop in the liquid level (41) of liquefied gas using the float (29),
2), a switch means consisting of a magnet (31), etc., and an alarm (36) can automatically notify that a predetermined remaining amount has been reached.

In addition, the flow (29) is designed taking into account the buoyant force required to operate the switch means, and the shaft (28) that holds the float (29) is made thinner than the shaft (28).
Since the influence of buoyancy caused by 8) can be reduced, the structure of the liquefied gas residual amount sensing section can be simplified.

Furthermore, if the shaft (28) is swingably provided by the connecting nut (24) and the flexible sleeve (25), even if the liquefied gas container (39) is tilted, no unreasonable force will be applied to the float (29). Moreover, it has the advantage of being able to issue a warning accurately.

[Brief explanation of drawings]

Figures 1 to 3 show one embodiment of the remaining amount indicator of the present invention. Figure 1 is an explanatory diagram of the main parts thereof, Figure 2 is an explanatory diagram showing the overall configuration, and Figure 3 is an illustration of the remaining amount. It is a cross-sectional explanatory view of a state where a quantity indicator is attached to a liquefied gas container. FIG. 4 is an explanatory cross-sectional view showing a conventional liquid level gauge. (20)...Remaining amount indicator (21)...Body (22)...Engaging part (22a)...Empty chamber (23)...Threaded part (23a)...
Vacancy (24)...Consolidated Nara) (24a)・
... Spherical part (24b) ... Tapered part (25)
...Flexible sleeve (25a)...Spherical part
(26)...Reinforcement spring (28)...Shaft
(29)... Float (31)... Magnet (32)... Magnet switch (36)... Alarm (39)... Liquefied gas container

Claims (1)

[Scope of Claims] 1. A main body attached to a liquefied gas container, a shaft provided on the main body so as to be movable up and down and housed in the liquefied gas container, and a float attached near the lower end of the shaft. , comprising a switch means provided on the main body and switched by movement of the shaft, and an alarm means provided outside the liquefied gas container and activated by the switch means, and when the float is exposed from the liquefied gas, the A remaining amount indicator for a liquefied gas container, characterized in that a switch means is activated to put the alarm means into an activated state. 2. A connecting member having a concave spherical part fixed to the main body, and a cylindrical body having a spherical part slidably held by the concave spherical part, and the shaft can move up and down on the cylindrical body. The remaining amount indicator for a liquefied gas container according to claim 1, which is attached to a liquefied gas container.