RU154929U1 - CONTAINER FOR GEOPHYSICAL EQUIPMENT FOR UNDERWATER RESEARCH - Google Patents

Abstract

1. The container for geophysical equipment during underwater exploration, which is a hollow body with a sealed lid, characterized in that the container contains gas under pressure, the value of which is determined by the depth of immersion, and the lid of the container is additionally equipped with a fitting with a shut-off valve. 2. The container according to claim 1, characterized in that the lid of the container is provided with a pressure seal. 3. A container according to claim 1, characterized in that the container is equipped with a pressure gauge installed inside the housing and a transparent window. The container according to claim 1, characterized in that the lid of the container is equipped with a pressure gauge.

Description

The utility model relates to measuring equipment, namely to devices that ensure the operation of geophysical instruments under water in the tightness mode. This device can be used in sonar to study acoustic fields of both natural and artificial origin.

When conducting various geophysical studies of the oceans, various types of sealed containers are widely used to protect geophysical equipment from contact with sea water, and often containers are immersed in water at great depths, where there is an external pressure many times higher than atmospheric. In such conditions, the reliability of sealing and the strength of the walls of the container becomes crucial for the safety of the equipment located inside and to ensure the fulfillment of the tasks. To ensure the strength and stability of the form, the developer is forced to use containers with a large wall thickness, which leads to an increase in the weight of the containers, most often far exceeding the weight of the protected equipment. In addition, the operation of equipment is often associated with the need for periodic removal of equipment from the container, which leads to the need for multiple opening / closing of the container itself, which, in turn, reduces the reliability of sealing due to additional wear of the sealing element, and due to the increased risk of violation sealing due to operating personnel errors.

The closest in purpose to the claimed utility model is a container that provides the work of hydroacoustic equipment that needs to be protected from contact with sea water (Shchurov V.A. Vector ocean acoustics. Vladivostok: Dalnauka, 2003, 308 s, p. 53, Fig. 2.9 ) The known device is a cylindrical metal container equipped with a sealed lid. Inside the container is placed the vector receiver equipment in the form of preliminary amplifiers, which must be protected from contact with sea water. To connect the amplifiers with the vector receiver, the cover is equipped with a pressure seal for connecting the cable. However, in the known device, in order to achieve sealing reliability at significant pressures, a case of considerable thickness is required, which leads to an increase in the weight and material consumption of the product. In addition, the device does not have a tightness control system, and its ability to maintain tightness under mechanical stress, for example, with external pressure arising when the container is submerged under water, it is determined only by the strength of the body material, its dimensions, including the wall thickness. Also, the tightness can be broken during operation as a result of, for example, erroneous actions of personnel in preparing the container for immersion under water.

The objective of the claimed model is the development of a container for geophysical equipment when conducting underwater research.

The problem is solved by a container for geophysical equipment during underwater research, which is a hollow body with a sealed cover, the container contains gas under pressure, the value of which is determined by the depth of immersion, and the cover is additionally equipped with a fitting with a shut-off valve.

The technical result of the claimed device is to reduce the weight and material consumption of the container, as well as reducing the risk of loss of the sealed geophysical equipment during operation during underwater research.

The device diagram is shown in Fig., Where

1 - container body, 2 - gas, 3 - geophysical equipment 4 - container cover, 5 - pressure gauge, 6 - fitting with shut-off valve.

The principle of application of the inventive device is based on the creation of tensile stresses in the container body (1) when there is gas inside the container (2) under a pressure lower than the liquid pressure when immersed to the working depth (Reference for resistance of materials / Pisarenko G.S., Yakovlev A .P., Matveev V.V. - Kiev: Science.Dumka, 1988 .-- 736 s).

The device operates as follows.

Gas (2) is pumped into a container containing geophysical equipment (3) using a boost compressor (not shown in the figure) connected to the container body (1) using a fitting (6) with a shut-off valve. In this case, tensile stresses arise in the container body (1), which will compensate for the compressive stresses that occur in the container body (1) when immersed under water, which allows the walls of the container body to be thinner than in the absence of gas under pressure. After creating the required gas pressure, the valve of the fitting (6) closes, the boost compressor is disconnected, and the manometer (5) is connected to the fitting (6) and the valve opens, and it becomes possible to observe the pressure change over time. A decrease in pressure is a sign of leakage. In the absence of the fact of pressure reduction within a specified time, the tightness of the container is considered sufficient and the container is put into operation, while the pressure gauge (5) can be disconnected if necessary.

The container can be additionally equipped with a manometer installed inside the container and a transparent window for monitoring and monitoring pressure changes over time during stand-alone operation.

The container can also be equipped with a pressure seal for cable transfer to the shore station.

The container body can be made of any material depending on operating conditions, for example, metal or alloy, as well as thermoplastic and thermosetting plastics.

Thus, the design features of the claimed device — the presence of pressurized gas in the container body and the presence of a sealed cover equipped with a fitting with a shut-off valve, can reduce weight and metal consumption, as well as significantly reduce the risk of loss of the sealed geophysical equipment due to loss of tightness during operation. In addition, the inventive device has structural simplicity and ease of use when conducting underwater research.

Claims (4)

1. The container for geophysical equipment during underwater exploration, which is a hollow body with a sealed lid, characterized in that the container contains gas under pressure, the value of which is determined by the depth of immersion, and the lid of the container is additionally equipped with a fitting with a shut-off valve. 2. The container according to claim 1, characterized in that the lid of the container is equipped with a pressure seal. 3. The container according to claim 1, characterized in that the container is equipped with a manometer mounted inside the housing and a transparent window. 4. The container according to claim 1, characterized in that the lid of the container is equipped with a pressure gauge.

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