NO20120683A1 - External radar dome on installations related to oil and gas production and exploration. - Google Patents

Abstract

The present invention relates to a radar dome (50) for use in hazardous ex-environments on installations related to oil and gas production and exploration, comprising a radar antenna (56) protected by a capsule (54), and the capsule is closed by a beam 5 (52) thereby providing an internal and closed environment, as well as a pneumatic system (60) for generating an overpressure inside the capsule (54), and comprising a flush control unit (9) for regulating and adjusting pressure within the capsule ( 54).

Description

Radar dome

The present invention relates to a radar dome for use in a hazardous ex-environment on installations related to oil and gas production and exploration.

A radome (the word is a combination of radar and dom) is a structural, waterproof capsule that protects a microwave or radar antenna. The radome is constructed of material that minimally weakens the electromagnetic signal sent or received by the antenna. In other words, the radome is transparent to radar or radio waves. Radomes protect the antenna surfaces from the weather or hide electronic antenna equipment from public view. They also protect nearby personnel from being harmfully struck by rapidly rotating antennae.

Radomes can be built in different shapes (spherical, geodesic, planar, etc.) depending on the particular application using different construction materials (fiberglass, PTFE-coated cloth, etc.).

The present ex-dome is a system designed primarily for ex-band radar, both with regard to physical dimensions and frequency, but can be used for all types of equipment that require an ex-protected capsule.

It is preferably built to meet European standard EN 60079-0:2009 and consists of a dome made of fiberglass composite and a support structure of stainless steel. It includes a flushing and overpressure control system to ensure an ex-safe environment. It also includes an ex-safe work light and an ex-safe energy outlet, as well as a disconnection-protected electrical distribution cabinet. An internally mounted gas detector is optional and can be retrofitted.

It is therefore an object of the present invention to produce a radar dome for use in an explosive environment, particularly on offshore installations for oil and gas production and exploration.

This purpose is achieved with a radar dome as defined in the independent claim, in that the radar dome comprises a radar antenna protected by a capsule where the capsule is closed by a bundle and thereby produces an internal and closed environment, and a pneumatic system to produce an overpressure inside the capsule, and includes a flushing control unit for regulation and setting of air pressure inside the capsule.

Preferred alternative embodiments are defined in the independent claims.

A programmable logic controller (PLC) can be connected to the pneumatic system and be designed to record pressure and temperature inside the dome.

The programmable logic controller (PLC) can also be arranged to maintain a desired pressure in the dome after the purge control unit has set the initial pressure by controlling a proportional valve inside the capsule.

A control valve in the pneumatic system can be arranged to keep the pressure between preset values, such as from 13 to 17 mbar.

The control valve can be adapted to supply control air to the proportional valve.

At least during flushing, an outlet valve can be arranged to be opened by the flushing control unit, and after a shutdown, the flushing control unit can be arranged to stop the flushing process by closing the outlet valve.

The invention will now be explained in more detail with the help of the accompanying drawings, where:

Fig. 1 shows an example of a radar dome according to the invention.

Fig. 2 shows a pneumatic system for the radar dome according to the invention.

Fig. 3 shows a flow chart for pressure regulation and flushing of the radar dome according to the invention. Fig. 1 schematically shows a radar dome 50 according to the invention. The radar dome comprises a waterproof capsule 54 placed on a pedestal 52, which in turn can be placed on any foundation. Inside the capsule 54 there is a radar antenna 56 which includes equipment for sending and receiving signals using the antenna.

An example of a pneumatic system for the radar dome according to the invention will now be explained further.

Examples of flush function/operation:

A flush control unit controls the air pressure together with the outlet valve Y4, which can also be described as a spark/particle fuse. Air is supplied to a regulator Y3, which can be set to 6 bar. Ex-solenoid valves Y1 are initially closed without any force. When switched on, a control device P1 activates Y1. Y1 directs pressure through Y6 and opens valve Y4. When this flow has reached a required quantity of liters per minute, the regulation device P1 starts a preset timer. This starting current is set to 0.3 mbar in the control device. The valve Y5 can be adjusted to keep the pressure at between 13 and 17 mbar, and it supplies regulation pressure to Y7. Y7 is controlled by PLC for regulation of pressure and temperature inside the radar dome. It usually has no function during flushing. Ports 1 and 2 in regulator P1 receive flow meter differential pressure, it does not conduct any air through itself. The pressures, flow rate and timer are adjustable. Y2 is a "mechanical" overpressure valve that is set to open at, for example, an overpressure of 1 bar.

Example of normal operation:

After the set flushing time, solenoid valve Y1 and valve Y4 close. The PLC will register the relevant pressure and the relevant temperature. To keep the climate stable, it will control Y7 which will help to maintain the desired pressure. If the pressure rises above 25 mbar, the system will disconnect the radar. If the pressure falls below the lower limit of 8 mbar, the control device P1 can disconnect the radar.

Example of system operation and startup:

Step 1: Turn on the 230V supply to the system. Open for the air supply to the radome. Check that the flushing control device's P1 display shows "no pressure" after a 15 sec. initialization phase.

Step 2: Confirm that the pressure gauge indicator reads 5-6 bar.

Step 3: Check that the outlet valve is opened by the flush control device.

Step 4: Check that the flush control device starts counting down

from the preset time after reaching its minimum flush current.

Step 5: After the countdown, check that the flush control device stops the flush process, which includes closing the outlet valve, and that the "cabinet pressure" on the display stabilizes between 13 and 17 mbar.

Step 6: Check that the radar has received power and check its operation.

Step 7: Check that the pressure inside the radome is stable for approx. 1 hour.

Parts list for fig. 2:

Claims (6)

1. Radar dome (50) for use in hazardous ex-environment on installations related to oil and gas production and exploration, comprising: - a radar antenna (56) protected by a capsule (54) where the capsule is closed by a bundle (52) and thereby produces an internal and closed environment, and - a pneumatic system (60) to produce an excess pressure in the capsule (54) and includes a flushing control unit (9) for regulation and setting of air pressure inside the capsule (54). 2. Radar dome (50) in accordance with claim 1, where a programmable logic controller (PLC) is connected to the pneumatic system (60) and arranged to record pressure and temperature inside the dome. 3. Radar dome (50) in accordance with claim 2, where the programmable logic controller (PLC) is arranged to maintain a desired pressure in the dome, after the flushing control unit (9) has set the output pressure, by controlling a proportional valve (21) inside in the capsule. 4. Radar dome (50) in accordance with claim 1, where a control valve (15) in the pneumatic system (60) is arranged to keep the pressure between preset values, such as from 13 to 17 mbar. 5. Radar dome (50) in accordance with claims 3 and 4, where the control valve (15) is arranged to supply control air to the proportionality valve (21). 6. Radar dome (50) according to claim 1, wherein, at least during flushing, an outlet valve (14) is arranged to be opened by the flushing control unit (9), and after a closing, the flushing control unit (9) is arranged to stop the flushing process by tightening the outlet valve (14).