JPH06235495A - Heat insulating pipe for injection and taking-out of liquefied natural gas to and from underground rock bed cavity - Google Patents

Abstract

PURPOSE:To provide a heat insulating pipe used to inject and take out liquefied natural gas between a base rock cavity formed underground and a ground facility. CONSTITUTION:Injection and taking-out pipelines 3 of LNG are arranged in a central part of a sectional surface, heat insulating material 4 is installed on the outer periphery of the aforementioned injection and taking-out pipelines 3, and additionally, on their outer periphery, a taking-out pipe 5 of nonfreezing solution is provided inside and an injection pipe 6 is provided outside in an inner and outer two layer structure. The taking-out pipe 5 and the injection pipe 6 are communicated with each other in one line, the taking-out pipe of nonfreezing solution and the injection pipe 6 are connected to a ground heat exchanging part 7, and on the outer periphery of the injection pipe 6 of nonfreezing solution, the heat insulating materials 4 are arranged. In this constitution, cold heat leaking from the pipelines 3 is constantly absorbed by nonfreezing solution flowing in the taking-out pipe 5 of nonfreezing solution, and accordingly, a sufficient heat insulating function is displayed. Additionally, as the cold heat absorbed by nonfreezing solution is collected by the heat exchanging part 3, it is possible to attempt efficient use of cold heat energy.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat insulating pipe for injecting / removing liquefied natural gas used for injecting or extracting liquefied natural gas between a rock cavity formed underground and a facility on the ground.

[0002]

2. Description of the Related Art As one of effective use of underground space, FIG.
As shown in FIG. 2, it has been proposed to construct a tank 10 for liquefied natural gas (hereinafter abbreviated as LNG) in the deep rock layer 1. However, at present, there is no case in which a cavity formed in a deep underground rock layer is put to practical use as an LNG tank. When using the cavity formed in the deep underground rock for the LNG tank, the heat insulating pipe 2 for injecting or taking out the LNG 12 is naturally provided between the ground facility 11 and the LNG tank 10. .
Insulation pipes for LNG, which have been put to practical use in the above-ground tanks or semi-underground tanks and are currently being adopted, perform heat insulation treatment,
The structure is devised to suppress the cold heat loss from the pipe as much as possible.

[0003]

[Problems to be solved by the invention] LNG12 stored in a cavity formed in deep underground rock is -162 ° C.
Since it is extremely low temperature, there is a possibility that adverse effects such as freezing may be exerted on the rock layer around the heat insulating pipe, the ground facilities 11, the support piles 11 'and the like. For this reason, it is necessary to provide the heat insulation pipe 2 with a sufficient heat insulation function, devise it so as not to freeze the rock layer around the pipe, collect the lost cold heat as much as possible, and measure the effective use of energy. In this respect, the heat-insulating pipes that have been practically used for LNG in the past have been heat-insulated by heat insulating materials, etc., but the heat-insulating function is not sufficient, that is, cold heat loss is not zero, and effective use of cold heat energy is not achieved. From a viewpoint, there is a request for improvement. Because,
It is expected that the surrounding rock layer will be gradually frozen when the above-mentioned heat insulating pipe is used for a long time, and further, the above-ground facility 11 and the support pile 11 ′ may be adversely affected.

Therefore, an object of the present invention is to improve the structure that has a sufficient heat insulation function to the extent that freezing is not adversely affected in the surrounding rock layer and above-ground facilities, and that cold energy can be effectively recovered. The purpose of the present invention is to provide an insulating pipe for injecting and extracting liquefied natural gas into the rock cavity.

[0005]

[Means for Solving the Problems] As means for solving the above problems, the heat insulating pipe for injecting and extracting liquefied natural gas into and from the underground rock cavity according to the present invention is a cavity formed in an underground rock layer. In a heat insulating pipe for injecting / removing liquefied natural gas arranged between the (LNG tank) and the above-ground facility, a liquefied natural gas injecting / removing pipe 3a, a gas pressure maintaining pipe 3b, and a boil-off are provided at the center of the cross section. An LNG inlet / outlet pipe line 3 composed of a gas exhaust pipe 3c is arranged, a heat insulating material 4 is installed on the outer circumference of the inlet / outlet pipe line 3, and an antifreeze take-out pipe is formed on the inside by a two-layer structure of the inner and outer layers. 5 and an injection pipe 6 on the outside, and the antifreeze take-out pipe 5 and the injection pipe 6 are underground LN.
In the upper part of the G tank 10, each lower end is connected in series, and a circulation flow path is formed in which the antifreeze liquid that has entered from the antifreeze liquid injection pipe 6 and dropped down is returned to the ground through the takeout pipe 5. The antifreeze liquid take-out pipe 5 and the injection pipe 6 are connected to the heat exchange section 7 on the ground to form a closed antifreeze liquid circulation path, and the heat insulating material 4 is arranged on the outer periphery of the antifreeze liquid injection pipe 6. , Respectively.

[0006]

[Function] The LNG injection / removal conduit 3 is set to a cryogenic LN
Even if G12 flows and the cold heat leaks from the pipe line 3 through the heat insulating material 4 on the outer periphery of the pipe line 12, the leaked cold heat is largely transferred to the antifreeze liquid take-out pipe 5 and the antifreeze liquid flowing in the outer injection pipe 6. Partially absorbed. A heat insulating material 4 is provided on the outer circumference of the injection pipe 6.
Is provided, the cold heat does not diffuse to the outer circumference of the heat insulating pipe 2. On the other hand, the antifreeze liquid cooled by the cold heat ascends in the take-out pipe 5 and is heat-exchanged in the heat exchanging portion 7, so that the cold heat can be effectively used. The antifreeze liquid, which has released cold heat and increased in temperature by the heat exchange, descends again in the injection pipe 6,
It flows to the take-out pipe 5 and repeats absorption and transportation of cold heat.

[0007]

Embodiments of the present invention will be described below with reference to the drawings. 1A and 1B are detailed views when the heat insulating pipe 2 of FIG. 2 is arranged between the LNG tank 10 provided in the underground rock layer and the ground facility 11. The heat insulating pipe 2 has an LNG injection / removal pipe line 3 at the center of its cross section.
Is installed. The LNG injection / removal pipeline 3 is
LNG inlet / outlet pipe 3a and gas pressure maintaining pipes 3b and L for adjusting or maintaining the gas pressure in the LNG tank 10.
It consists of a boil-off gas discharge pipe 3c for discharging boil-off gas in the NG tank 10, and the respective pipes are installed in parallel at appropriate intervals and surrounded by a heat insulating material 4 having a sufficient thickness.

On the outer periphery of the above-mentioned injection / removal pipe line 3, an antifreezing liquid retrieving pipe 5 is formed on the inner side as an inner / outer two-layer structure partitioned by concentric partitions.
The injection pipe 6 is installed outside. Further, a heat insulating material 4 is arranged on the outer circumference of the outer injection pipe 6. The cold heat leaked from the injection / extraction pipe line 3 is directly absorbed by the antifreeze liquid rising inside the antifreeze liquid extraction pipe 5 arranged inside. Removal pipe 5 and injection pipe 6 for the antifreeze liquid
Is partitioned into appropriate sizes in the circumferential direction by the partition, and by forming a subdivided flow path, stagnation or deflection of the flow of the antifreeze liquid is prevented.
The lower ends of the antifreeze take-out pipe 5 and the injection pipe 6 are made of LN.
The G tank 10 is connected in series at the upper portion, and the upper end portion of each is connected to the ground heat exchange portion 7. Thus, the heat exchange section 7, the antifreeze liquid take-out pipe 5 and the injection pipe 6 form a closed antifreeze liquid circulation circuit.

Next, the function of the heat insulating pipe 2 having the above construction will be described. When cryogenic cold heat leaks out from the LNG injection / extraction pipe line 3 through the heat insulating material 4 on the outer periphery thereof, this cold heat is first absorbed by cooling the antifreeze liquid flowing upward in the antifreeze liquid extraction pipe 5. , Rises together with the antifreeze to reach the heat exchange section 7 on the ground. Even if the cold heat leaks to the injection pipe 6 outside the take-out pipe 5, it is absorbed by the antifreezing liquid descending in the pipe. Further, the heat insulating material 4 on the outer circumference of the injection pipe 6 also achieves a sufficient heat insulating function. Therefore, the rock layer around the heat insulating pipe 2 and the ground facilities 11 are not adversely affected by freezing due to cold heat. On the other hand, the antifreeze liquid cooled by cold heat as described above is conveyed to the heat exchange section 7 on the ground through the take-out pipe 5, and the cold heat is recovered in the heat exchange section 7, so that the antifreeze solution is used for cooling on the ground and the like. Effective use of energy is achieved.

The antifreeze liquid whose temperature has risen due to the heat exchange passes through the injection pipe 6 and descends the heat insulating pipe 2 again, flows to the extraction pipe 5, and cools the cold heat leaking from the LNG injection / extraction pipe line 3. The absorption cycle is sequentially repeated. In this way, the antifreeze liquid circulates in the closed circulation circuit and constantly absorbs the cold heat leaking from the LNG inlet / outlet pipe line 3, thereby sufficiently enhancing the heat insulating function of the heat insulating pipe 2.

[0011]

EFFECTS OF THE INVENTION According to the heat insulating pipe 2 for injecting / removing liquefied natural gas into the underground rock cavity according to the present invention, the cold heat leaking out from the LNG injecting / extracting pipe line 3 at the center thereof is the antifreeze liquid. Since it is constantly absorbed by the antifreeze liquid flowing in the take-out pipe 5, the surrounding rock layer and ground facilities will not be adversely affected by freezing due to cold heat.
Exhibits sufficient heat insulation function. At the same time, the cold heat absorbed by the antifreeze can be recovered by the heat exchange section 3 to effectively utilize the cold heat energy.

[Brief description of drawings]

FIG. 1A is a cross-sectional view of a heat-insulating pipe installed, and B is a horizontal (transverse) cross-sectional view of the heat-insulating pipe.

FIG. 2 is a schematic diagram showing an LNG tank in underground rock.

[Explanation of symbols]

 1 Bedrock 2 Insulation Pipe 3 LNG Injecting / Extracting Pipeline 4 Insulating Material 5 Antifreeze Extracting Pipe 6 Antifreeze Injecting Pipe 7 Heat Exchange Section 10 LNG Tank

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Takao Ueda 2-5-14 Minamisuna, Koto-ku, Tokyo Inside the Takenaka Corporation Technical Research Institute (72) Inventor Yuichi Komura 2-5, Minamisuna, Koto-ku, Tokyo No. 14 Stock Company Takenaka Corporation Technical Research Institute

Claims (1)

[Claims] 1. A heat insulating pipe for injecting and extracting liquefied natural gas, which is arranged between a cavity formed in underground rock and an above-ground facility, injecting liquefied natural gas into the center of the cross section.
A liquefied natural gas injection / removal pipeline consisting of a retrieving pipe, a gas pressure maintaining pipe, and a boil-off gas exhaust pipe is arranged.
A heat insulating material is installed on the outer circumference of the injection / removal pipe line, and further, an antifreeze take-out pipe is provided on the inner side of the outer and outer two-layer structure and an injection pipe is provided on the outer side thereof. The lower end of each of the injection pipes is connected in series at the upper part of the underground rock cavity, and the antifreeze liquid that has entered from the antifreeze liquid injection pipe has a circulation flow path that returns to the ground through the extraction pipe. The take-out pipe and the injection pipe are connected to a heat exchange section on the ground to form a closed antifreeze circuit, and a heat insulating material is provided around the antifreeze injection pipe. A heat insulation pipe for injecting and extracting liquefied natural gas into the underground rock cavity.