JP4641422B2 - Spherical gas holder - Google Patents

Description

  The present invention relates to a spherical gas holder. More specifically, the present invention does not require spacers for the gas inlet and the gas outlet, does not require management of the gas storage amount by a limit switch or the like, and even if the gas storage amount decreases, The present invention relates to a spherical gas holder in which the gas-filled portion where the take-out speed does not decrease is composed of a rubber-drawn cloth or a plastic-drawn balloon.

Spherical gas holders are widely used for storing city gas, industrial gas such as hydrogen gas and oxygen gas. The spherical gas holder used for such a purpose is large-sized, and high-strength steel or the like is used as the material, and the service life is expected to be long. On the other hand, digestion gas generated from sewage treatment plants and barns is relatively small compared to city gas, industrial gas, etc., and long-term durability is often not required for storage facilities. . Gas holders made of rubber cloth or plastic cloth have been developed as gas holders for gases that have a small amount of handling and a short equipment renewal period.
FIG. 10 is a side view of an example of a conventional gas holder made of rubberized cloth. In the gas holder of this example, a bag body 22 having a bellows structure made of rubber or plastic is installed on a base plate 24 in a frame 23. At the lower part of the bag body, a gas inlet 25 and a gas outlet 26 are provided through the base plate. A top plate 27 is placed on the bag body, and a weight 28 is further placed on the top plate.
In the gas holder of this example, when the gas inlet is closed and gas is fed from the gas inlet, the bellows-structure rubber or plastic bag is inflated, and the top plate with the weight is raised. When the gas inlet is closed and the gas outlet is opened, the gas inside the bag flows out at a pressure given by the weight. The pressure inside the bag can be adjusted by the weight of the weight, and the gas holder having this structure can withstand an internal pressure of about 2 kPa. The gas holder in this example requires almost no foundation work, and since the bag is folded at the start of use, it is not necessary to replace the gas inside. Since the bellows-structured rubberized plastic cloth or plastic plastic cloth bag is folded, the frame is disassembled and transported, assembled on site, and used immediately, it can be installed simply, easily and inexpensively. However, since manufacturing of a bellows-structured rubberized cloth or plastic-clothed bag takes much time and repair is not easy, a simpler spherical gas holder has been developed.
FIG. 11 is a side view of an example of a conventional spherical gas holder. This figure shows a state in which a spherical holder balloon is completely filled with gas. In this spherical gas holder, the gas filling portion is made of a rubber or plastic balloon 29, and when the gas is completely filled, the balloon is substantially spherical. A gas inlet 30 and a gas outlet 31 are formed at the lower end of the balloon. The equator of the balloon is supported by a frame made up of a pedestal 32 and a ring 33. The balloon is fixed to the ring by a belt (not shown) provided at the equator of the substantially spherical balloon.
When the balloon is not filled with gas, the upper half of the balloon falls inward, and the balloon is generally bowl-shaped. When the gas inlet is closed and gas is fed from the gas inlet, the upper half of the balloon gradually rises, and when the gas is completely filled, the balloon has a substantially spherical shape. When the gas inlet is closed and the gas outlet is opened, the upper half of the balloon descends and gas is sent out from the gas outlet. A substantially spherical balloon can be manufactured more easily than a bag with a bellows structure, and a frame that supports a substantially spherical balloon has a simple structure compared to a frame that supports a bellows structure. Gas holders can be economically manufactured and installed.
However, the spherical gas holder has a problem that when the gas storage amount decreases, the gas inlet and the gas outlet are covered by the upper half of the balloon that has fallen inward, and the gas inlet speed and the gas outlet speed are significantly reduced. It was. As a countermeasure, at present, there are spacers at the top of the gas inlet and the gas outlet, and a means to keep the gas inlet and the gas outlet not covered even when the upper half of the balloon is lowered, or a limit switch is installed. Means are provided for managing the amount of gas stored and controlling the upper half of the balloon not to fall before the gas inlet and the gas outlet are covered. However, the provision of spacers or limit switches is reasonably expensive and some of the characteristics of the spherical gas holder that are low cost are impaired. In addition, the management by the limit switch not only requires man-hours for setting the minimum capacity, but also has a drawback that the original capacity of the spherical gas holder cannot be fully utilized.

  The present invention does not require a gas inlet / outlet spacer, does not require the management of gas storage by a limit switch, etc., and the gas inflow rate and gas extraction rate are reduced even when the gas storage amount decreases. The object of the present invention is to provide a spherical gas holder in which the gas-filled portion is made of a balloon of rubberized cloth or plastic cloth.

As a result of intensive studies to solve the above problems, the inventors of the present invention have conventionally used a spherical gas holder in which the equator of the balloon is supported in order to maximize the operating capacity. By supporting the upper part, even if the upper half of the balloon descends to the maximum, the gas inlet and the gas outlet are not covered, and smooth gas inflow and extraction are possible without the need for spacers or limit switches. It has been found that it is possible to carry out stably, and the present invention has been completed based on this finding.
That is, the present invention
(1) A gas holder having a gas filling part comprising a rubber or plastic cloth balloon, a gas inlet and a gas outlet at the lower end, and a holder balloon that is substantially spherical when fully filled with gas. A spherical gas holder characterized in that the upper part of the equatorial part of a substantially spherical balloon is supported by a frame at an interval of 5 to 30 cm;
(2) The spherical gas holder according to (1), wherein the inner diameter of the balloon support ring of the frame is 1 to 1.1 times the diameter of the equator of the balloon;
(3) The spherical gas holder according to (1), comprising a weight at the apex of the substantially spherical balloon,
(4) The spherical gas holder according to (3), wherein the weight is provided inside the apex of the substantially spherical balloon.
(5) The spherical gas holder according to (1), wherein a plurality of annular weights having a center on the central axis of a substantially spherical balloon are attached to the surface of the upper half of the balloon.
(6) The spherical gas holder according to (5), wherein the annular weight is made of a metal rod,
(7) The spherical gas holder according to (5), wherein the annular weight is made of a metal chain, and
(8) A wire is attached to the apex of a substantially spherical balloon, the wire is suspended vertically via a pulley, and the amount of gas stored in the balloon is determined based on the position of the wire. Spherical gas holder,
Is to provide.

  The spherical gas holder of the present invention can be economically manufactured using a rubber or plastic pulling cloth, and the upper part of the equator of the substantially spherical balloon is supported by the frame at 5 to 30 cm. Even if the amount is minimized, the gas inlet and the gas outlet are not covered by the upper half of the balloon, and the gas can be smoothly introduced and extracted.

The spherical gas holder of the present invention comprises a balloon made of rubber or plastic, the gas filling part has a gas inlet and a gas outlet at the lower end, and is a holder balloon that forms a substantially spherical shape when completely filled with gas. A spherical gas holder in which the upper part of the equator of a substantially spherical balloon is supported by 5 to 30 cm by a frame.
FIG. 1 is a side view of one embodiment of the spherical gas holder of the present invention. This figure shows a state in which the balloon is completely filled with gas. The spherical gas holder of this embodiment is composed of a rubber-filled cloth or a plastic-drawn balloon 1 in the gas filling portion, and has a gas inlet 2 and a gas outlet 3 at the lower end. It is spherical, and the upper part of the equator of the balloon is supported by a frame composed of the pillars 4 and the rings 5. That is, the distance d between the equator of the balloon indicated by the alternate long and short dash line and the support line indicated by the dotted line in the figure is 5 to 30 cm. The balloon is fixed to the ring by a belt (not shown) provided 5-30 cm above the equator. The equator is a circle formed when the balloon is cut on a horizontal plane passing through the center of the substantially spherical balloon. FIG. 2 is a cross-sectional view of the spherical gas holder shown in FIG. This figure shows a state in which the balloon is completely filled with gas. The one-dot chain line in the figure is the equator of the balloon, and the dotted line is the support line of the balloon. All cross-sectional views including the following cross-sectional views show cross sections cut by a plane including a substantially spherical vertical diameter.

In the spherical gas holder of the present invention, the method of supporting the holder balloon by the frame is not particularly limited. For example, the balloon is secured to the balloon support ring of the frame by using a rope, a string, a belt or the like attached to the balloon. Alternatively, a seat made of rubberized cloth or the like attached to the balloon can be fixed to the balloon support ring using bolts, rivets or the like. In the present invention, a single pipe for the balloon serving as the gas inlet and the gas outlet can be used, and the gas inlet and the gas outlet can also be used by switching a valve or the like.
FIG. 3 is a cross-sectional view showing a state where the gas storage amount of the spherical gas holder shown in FIG. 1 is minimized. As the gas storage volume decreases, the upper half of the balloon gradually descends. When the equatorial part of the substantially spherical balloon is supported by the frame, when the gas storage amount of the balloon becomes zero, the upper half of the balloon overlaps with the lower half of the balloon, resulting in a substantially hemispherical saddle shape. As a result, the gas inlet and the gas outlet are covered by the upper half of the balloon, and the gas inflow rate and the gas extraction rate are significantly reduced. In the spherical gas holder of the present invention, the upper portion of the equator of the substantially spherical balloon is supported by the frame at 5 to 30 cm, so that a gap 6 is formed between the upper half and the lower half of the balloon, and the gas inlet and the gas Even when the take-out port is not covered and the gas storage amount is minimized, the gas can be smoothly flowed in and out.

In the spherical gas holder of the present invention, the upper part of the equatorial part of the substantially spherical balloon is supported by the frame at 5 to 30 cm, more preferably 10 to 20 cm. In the spherical gas holder shown in FIGS. 1 and 2, when the distance between the equator of the balloon and the support line of the balloon is d, it is formed by the lower half and the upper half of the balloon when the gas storage amount of the balloon is minimized. The interval is approximately 2d. When the distance between the support line of the substantially spherical balloon by the frame and the equator is less than 5 cm, the distance between the gas inlet / outlet and the upper half of the balloon becomes small when the gas storage amount of the balloon is minimized. Inflow and extraction of gas may be hindered. If the distance between the support line of the substantially spherical balloon by the frame and the equator exceeds 30 cm, the amount of gas that can be taken out and cannot be used in the balloon increases, and the volume of the balloon that cannot be used may become excessive. The distance d between the equator of the balloon and the support line of the balloon can be appropriately selected according to the capacity of the balloon, the material of the rubberized cloth or plastic cloth that constitutes the balloon, and the like.
In the spherical gas holder of the present invention, the inner diameter of the balloon support ring of the frame is preferably 1 to 1.1 times the diameter of the equator of the balloon, more preferably 1.01 to 1.05 times. preferable. If the inner diameter of the balloon support ring is less than 1 times the diameter of the equator of the balloon, the support ring may become an obstacle and it may be difficult to completely fill the balloon with gas. When the inner diameter of the balloon support ring exceeds 1.1 times the diameter of the equator portion of the balloon, the means for fixing the balloon such as a belt becomes long, and it may be difficult to stably support the balloon.

The spherical gas holder of the present invention can be provided with a weight at the apex of a substantially spherical balloon. FIG. 4 is a side view of another embodiment of the spherical gas holder of the present invention. This figure shows a state in which the balloon is completely filled with gas. The spherical gas holder of this embodiment is provided with a weight 7 at the apex of a substantially spherical balloon 1. By providing a weight at the apex of the substantially spherical shape and adjusting the weight, the inside of the balloon filled with gas can be pressurized to a predetermined pressure. The spherical gas holder of the present invention can keep the pressure inside the balloon at about 300 Pa.
In the spherical gas holder of the present invention, it is preferable to install the weight inside the apex of the substantially spherical balloon. There is no particular limitation on the method of placing the weight inside the balloon. For example, a molded body of rubber or plastic having a surface in contact with the inner surface of the balloon is manufactured, a hook is attached to the molded body, and the molded body is attached to the apex of the balloon. The weight can be hung from the hook and a belt can be attached to the inside of the apex of the balloon, and the weight can be attached by the belt.

FIG. 5 is a cross-sectional view of another embodiment of the spherical gas holder of the present invention. This figure shows a state in which the balloon is completely filled with gas. A molded body 8 having a surface in contact with the inner surface of the balloon is bonded to the inside of the apex of the substantially spherical balloon 1, and a weight 9 is suspended from a hook attached to the molded body. By providing a weight inside the apex of the generally spherical balloon, when the gas storage volume decreases and the upper half of the balloon descends, the weight descends on the vertical diameter of the generally spherical balloon.
FIG. 6 is a cross-sectional view showing a state where the gas storage amount of the spherical gas holder shown in FIG. 4 is reduced. In the spherical gas holder of this embodiment, when the gas storage amount decreases and the upper half of the balloon descends, the weight descends on the vertical diameter indicated by the dashed line in the figure, and the balloon is always symmetrical with the vertical diameter. Maintain a rotationally symmetrical shape about the axis. In the spherical gas holder shown in FIG. 4 where the weight is outside the apex of the substantially spherical balloon, when the gas storage volume decreases and the upper half of the balloon descends, the weight does not necessarily fall on the approximately spherical vertical diameter. Without tilting, the balloon tends to be irregularly shaped, tilting back and forth and left and right.

In the spherical gas holder of the present invention, a plurality of annular weights whose centers exist on the central axis of the substantially spherical balloon can be attached to the surface of the upper half of the balloon. FIG. 7 is a side view of another embodiment of the spherical gas holder of the present invention. This figure shows a state in which the balloon is completely filled with gas. In the spherical gas holder of this embodiment, three annular weights composed of metal rods 10, 11 and 12 having a center on the central axis of the substantially spherical balloon are formed on the surface of the upper half of the substantially spherical balloon 1. It is attached. A gas inlet 2 and a gas outlet 3 are provided at the lower end of the balloon. A weight 13 is provided at the apex of the substantially spherical balloon, a wire 14 is attached to the weight as a level meter, and the position of the end 15 of the wire suspended vertically through the pulley is read by the scale 16 , Know the position of the top of the balloon. In the present invention, the metal rod forming the annular weight is not particularly limited, and examples thereof include a PC steel rod, a stainless steel rod, a cold-finished stainless steel rod, and the like.
FIG. 8 is a cross-sectional view showing a state in which the spherical gas holder shown in FIG. In this state, about 50% by volume of the gas in the substantially spherical balloon is exhausted. As shown in FIG. 8, the spherical gas holder of this embodiment has a one-to-one relationship between the apex position of the balloon and the inner volume of the balloon because the top surface 17 of the balloon is maintained in a substantially horizontal plane during gas extraction. The relationship holds. Therefore, a graph showing the relationship between the position of the apex of the balloon and the internal volume of the balloon is prepared in advance, and the amount of gas stored in the spherical gas holder can be read from the graph, or the end 15 of the wire moves. The scale of the scale 12 provided in the range to be used can be used as the inner volume of a substantially spherical balloon to directly read the gas storage amount.

In the spherical gas holder of the present invention, a metal chain can be used as an annular weight. FIG. 9 is a side view of another embodiment of the spherical gas holder of the present invention. This figure shows a state in which the balloon is completely filled with gas. In the spherical gas holder of this embodiment, three annular weights comprising metal chains 18, 19 and 20 having a center on the central axis of the substantially spherical balloon are attached to the surface of the upper half of the substantially spherical balloon. Further, these three annular weights are connected by six longitudinal metal chains (three on the back side and not shown) 21. A gas inlet 2 and a gas outlet 3 are provided at the lower end of the balloon. A weight 13 is provided at the apex of the substantially spherical balloon, a wire 14 is attached to the weight, and the position of the end 15 of the wire suspended vertically through the pulley is read by the scale 16 to thereby read the balloon. You can know the position of the vertex. A weight made of a metal chain has better followability to the deformation of the balloon than a weight made of a metal rod. In the present invention, the metal chain forming the annular weight is not particularly limited, and examples thereof include a transmission roller chain and a chain block link chain.
The spherical gas holder of the embodiment shown in FIG. 9 also has a one-to-one relationship between the position of the balloon apex and the inner volume of the balloon because the top surface of the balloon maintains a substantially horizontal plane during gas extraction. Therefore, a graph showing the relationship between the position of the apex of the balloon and the internal volume of the balloon is prepared in advance, and the amount of gas stored in the spherical gas holder can be read from the graph, or the end 15 of the wire moves. The scale of the scale 16 provided in the range to be used can be used as the inner volume of a substantially spherical balloon, and the gas storage amount can be directly read.

No particular limitation is imposed on the capacity of the spherical gas holder of the present invention, it is preferably 1～300M ^3, and more preferably 5 to 200 m ^3. Since general-purpose general-purpose products are commercially available for gas holders with a capacity of less than 1 m ³ , commercial products can be purchased and used economically. If the capacity exceeds 300 m ³ , the strength is insufficient with rubber or plastic cloth, so it is preferable to make a metal gas holder depending on the pressure.
There is no restriction | limiting in particular in the material of the base fabric of the rubber | gum pulling cloth used for this invention, or a plastics pulling cloth, For example, a cotton fabric, a polyester fabric, a polyamide fabric etc. can be mentioned. There are no particular restrictions on the rubber material of the rubberized cloth used in the present invention. For example, natural rubber (NR), isoprene rubber (IR), styrene-butadiene rubber (SBR), butadiene rubber (BR), chloroprene rubber (CR). Acrylonitrile-butadiene rubber (NBR), ethylene-propylene-diene rubber (EPDM), butyl rubber (IIR), and the like. Among these, styrene-butadiene rubber, chloroprene rubber, acrylonitrile-butadiene rubber and ethylene-propylene-diene rubber can be suitably used. There is no restriction | limiting in particular in the plastic material of the plastic pulling cloth used for this invention, For example, a polyurethane, a polyvinyl chloride, a nitrocellulose etc. can be mentioned. Among these, polyurethane can be preferably used.

The rubber or plastic fabric used in the present invention is preferably free of abnormalities with no load at 500 times and more preferably free of abnormalities with no load at 1,000 times in the paddle test. If an abnormality occurs at 500 no load, the durability as a gas holder may be insufficient. The rubber cloth or plastic cloth used in the present invention is preferably 5.0 cm ³ / (m ² · s · Pa) or less in a gas permeation test using a stored gas, and preferably 3.0 cm ³ / ( m ² · s · Pa) or less is more preferable, and 1.0 cm ³ / (m ² · s · Pa) or less is more preferable. If the result of the gas permeation test exceeds 5.0 cm ³ / (m ² · s · Pa), the leakage of gas from the spherical gas holder may reach a level that cannot be ignored. A rubber test of a rubber or plastic fabric can be performed using a Scott type tester according to JIS K 6404-6. The gas permeation test of rubber or plastic fabric can be performed according to JIS K 6404-10 by test method B1 using a Cambridge gas permeation test apparatus or test method B2 using a manometer type gas permeation tester.

In the spherical gas holder of the present invention, the upper part of the equator of the substantially spherical holder balloon is supported by 5 to 30 cm by the frame, so that the gas provided at the lower end of the balloon is reduced even when the gas storage amount of the balloon is minimized. The inlet and the gas outlet are not covered by the upper half of the balloon, and the gas can be stably supplied without the need to protect the gas inlet and the gas outlet with a spacer or manage the gas storage volume with a limit switch. Can be introduced and removed.
The spherical gas holder of the present invention can be economically manufactured by using a rubber cloth or a plastic cloth, and can be easily transported, installed, maintained and removed. The spherical gas holder of the present invention can be suitably used for storing small-scale gas such as digestion gas generated from a sewage treatment plant, a livestock barn, a methane fermentation tank or the like.

It is a side view of one mode of a spherical gas holder of the present invention. It is sectional drawing of the spherical gas holder shown in FIG. It is sectional drawing which shows the state which gas storage amount became the minimum. It is a side view of the other aspect of the spherical gas holder of this invention. It is sectional drawing of the other aspect of the spherical gas holder of this invention. It is sectional drawing which shows the state which the gas storage amount decreased. It is a side view of the other aspect of the spherical gas holder of this invention. It is sectional drawing which shows the state during the gas extraction of the spherical gas holder shown in FIG. It is a side view of the other aspect of the spherical gas holder of this invention. It is a side view of an example of the gas holder made from the conventional rubberized cloth. It is a side view of an example of the conventional spherical gas holder.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Balloon 2 Gas inflow port 3 Gas outlet 4 Leg column 5 Ring 6 Gap 7 Weight 8 Molded body 9 Weight 10 Metal rod 11 Metal rod 12 Metal rod 13 Weight 14 Wire 15 End of wire 16 Scale scale 17 Balloon 18 Metal Chain 19 Metal Chain 20 Metal Chain 21 Metal Chain 22 Bellows Structure Bag 23 Frame 24 Base Plate 25 Gas Inlet 26 Gas Outlet 27 Top Plate 28 Weight 29 Balloon 30 Gas Inlet 31 Gas Outlet 32 Leg Pillar 33 Ring

Claims (8)

  A gas holder having a gas balloon and a plastic cloth balloon, having a gas inlet and a gas outlet at the lower end, and having a substantially spherical holder balloon when the gas is completely filled; A spherical gas holder, wherein an upper part of an equatorial part of a substantially spherical balloon is supported by a frame at a distance of 5 to 30 cm.   2. The spherical gas holder according to claim 1, wherein the inner diameter of the balloon support ring of the frame is 1 to 1.1 times the diameter of the equator of the balloon.   2. A spherical gas holder according to claim 1, wherein a weight is provided at the apex of the substantially spherical balloon.   4. A spherical gas holder according to claim 3, wherein the weight is provided inside the apex of the substantially spherical balloon.   2. The spherical gas holder according to claim 1, wherein a plurality of annular weights having a center on the central axis of the substantially spherical balloon are attached to the surface of the upper half of the balloon.   6. The spherical gas holder according to claim 5, wherein the annular weight is made of a metal rod.   6. The spherical gas holder according to claim 5, wherein the annular weight is made of a metal chain.   2. A spherical gas holder according to claim 1, wherein a wire is attached to the apex of the substantially spherical balloon, the wire is suspended vertically via a pulley, and a gas storage amount in the balloon is determined based on the position of the wire. .

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