NO347059B1 - Habitat case - Google Patents

Description

Background

Society's development is increasingly based on network solutions for equipment to transport data information. Fiber cables and equipment have become and will be a large part of this technology.

Fiber splicing in the oil and gas sector is defined as hot work due to the high temperature generated during splicing, which is a temperature of around 1800 degrees Celsius. Many gases have a low auto-ignition temperature that can be well below approx. 1800 degrees Celsius, and therefore there is a need to be able to control the environment around the fiber splice itself in areas where there is a risk of gas leaks and/or the presence of flammable gas(es) ). The need for simple solutions around the use of fiber splices has become a necessity.

US 2013/0336621 A1 relates to an enclosure system for enclosing a fiber splicing device so that the fiber splicing device can be used in a hazardous area. The enclosure system consists of an enclosure, where the upper side of the enclosure is adapted to be a door to the enclosure, and a flushing or blowing unit is connected to the enclosure to carry out pressure flushing inside the enclosure system, where the blowing unit comprises a pressure flushing unit, an air pump device and pressure gauges. A fusion splicer and fiber optic cables to be spliced together are arranged inside the enclosure, and the upper side of the enclosure is locked and sealed by means of a sealing unit. The sealing unit is made of soft materials that adapt to the fiber optic cables to be spliced, and therefore do not damage the fiber optic cables. By using the blower unit of the enclosure system, a flammable gas inside the fiber optic enclosure system is displaced with non-flammable air or inert gas. During splicing, the enclosure system also maintains positive pressure inside the enclosure, thereby preventing a flammable gas from entering the enclosure.

GB 2588858 relates to a device cover for shielding an electronic device, such as a smartphone, from an external environment, the device cover comprising: a front cover configured to at least partially cover a surface of the electronic device, a front window configured to be placed under the front cover; an outer frame configured to be positioned below the front window, the outer frame comprising a circumferential wall defining a cavity; and an inner frame comprising a peripheral wall configured to be located within the outer frame, at a position adjacent an inner surface of the outer frame's peripheral wall. The inner frame comprises at least a first flange portion extending from an edge of the inner frame's peripheral wall and extending over an edge of the outer frame's peripheral wall. The first flange portion is designed to provide a seat along an edge of the peripheral wall of the outer frame. The cover also includes a rear window configured to be placed under the outer frame, the rear window comprising an electromagnetic penetrating material; a rear cover configured to be positioned below the rear window and configured to at least partially cover a surface of the electronic device; and at least one screw configured to secure together the components to the electronic device cover.

US 2006/0263016 A1 describes an apparatus and a method for fusion splicing of optical fibers.

US 2015/0177461 A1 relates to an explosion-proof optical fiber splicing system.

There are several types of fiber devices with different controls. Some fiber devices come with a control panel that can be turned to either a horizontal or a vertical position, and some that can only be operated on top of the fiber device. What is known in the art relies on physical buttons mounted on the front of a box to be able to operate the fiber device internally, which means that the known boxes in the field are only compatible with one type of fiber device, i.e. a fiber device with a reversible control panel. In addition, the placement of the fiber device must be exact in order to hit the physical fixed push buttons on the known box. If the fiber apparatus moves inside the known box, the procedure for pressurizing the box must be started again.

Summary of the invention

The aim and purpose of the present invention is to reach a larger cooperative market of users as this is to be considered a universal product where all fiber splicing devices fit into a habitat case according to the invention and can be easily operated. It is the same whether the fiber device is of the type with control only at the top or with a tiltable control panel.

The main features of the present invention appear from the independent patent claims. Further features of the invention are indicated in the independent patent claims.

The invention relates to a habitat case. The habitat case can be approximately cubic or square prism-shaped. The habitat case is configured for fiber splicing in a surrounding work area where there is a risk of the presence and/or leakage of at least one flammable gas. The habitat case includes:

- a first fiber feedthrough and a second fiber feedthrough which are symmetrically arranged on two opposite parallel walls of the habitat case in order to thereby remedy the splicing of two optical fibers which are each inserted into the respective fiber feedthrough;

- a cable feed-through which is arranged on the habitat case and which is configured for power supply to a fiber splicing apparatus which is placed inside the habitat case;

- a first plug-in nipple which is arranged on the habitat case and which is configured for connection, via a first hose, to a regulator with a manometer and with a plug-in nipple for connecting an external supply of air and/or a non-flammable gas, as it the external supply creates and maintains an overpressure in the habitat case;

- a second insertion nipple which is arranged on the habitat case and which is configured for connection to a differential pressure gauge via a second hose; and

- a fully or partially transparent window which is arranged on a large wall of the habitat case. The large wall lies between the two opposite walls with the fiber penetrations and is perpendicular to them. The window is made of an elastic material, thereby ensuring the operation of the fiber splicer. The elastic material for the window can be chosen from one of: rubber, silicone and/or compatible with touch screens.

The habitat case can also include at least one ventilation nipple to thereby ensure air flow in the habitat case. The at least one ventilation nipple can be arranged in one of the walls of the habitat case.

One of the large walls of the habitat case can form a lid. The lid can be fitted with hinges and at least one locking bracket. The at least one locking bracket may be configured to cooperate with at least one respective lock that is arranged on a wall of the habitat case.

The elastic window can be arranged on the lid.

The habitat case can further comprise a gasket which is arranged to seal between the edges of the lid and the respective four wall edges of the habitat case and which functions as a sealing surface to prevent large pressure drops therein. The gasket can be made of a soft material, such as rubber and/or silicone.

The penetrations for fiber and cable supply can be padded with a brush-shaped material to thereby ensure that fiber and cable are not damaged when using the habitat case.

The habitat case can further comprise a handle which is arranged on one of the walls of the habitat case.

In order to withstand the overpressure, the habitat case can be made of one of: stainless steel, alloys, metals and/or other hard and strong materials, such as for example ss316 and/or composite.

The invention also relates to a protection system configured for fiber splicing in a surrounding work area where there is a risk of the presence and/or leakage of a flammable gas.

The protection system includes:

- the existing habitat portfolio;

- a fiber splicing apparatus which is placed into the habitat case and which is configured for splicing two optical fibers which have been introduced into the habitat case via the fiber feedthroughs, the fiber splicer being supplied with power from an external power source via the cable feedthrough for power supply;

- a regulator which has a manometer and an insertion nipple and which is connected to the habitat case via a first hose;

- an external supply for air and/or a non-flammable gas, the external supply being configured to supply air and/or a non-flammable gas to the habitat case via the regulator's plug-in nipple, the external supply being further configured to form and maintain an overpressure in the habitat case, and the regulator is configured to regulate and/or maintain the overpressure in the habitat case in the range from about 0.1 bar to about 2 bar; and

- a differential pressure gauge which is connected to the habitat case via a second hose and which is configured to ensure and/or verify a differential pressure between the internal excess pressure in the habitat case and the atmospheric pressure outside the habitat case 100, and to regulate and/or maintain the differential pressure in a range from approx. 30 pascal to approx. 70 pascal.

Drawings

Figure 1 shows a habitat case according to the present invention in an open state and with associated equipment.

Figure 2 shows the habitat case according to the invention in a closed state and with associated equipment.

Detailed description of the invention

The figures show a habitat case 100 which is designed to reduce the scope around fiber splices in classified zones (where there is a risk of the presence and/or leakage(s) of at least one flammable gas in a work area) in the oil and gas sector. Normally, this will require an approved or full-fledged habitat to be able to splice fiber(s) in a classified zone. This is significant work and requires extra time and additional staffing to be able to build and/or operate such a habitat, and this is normally carried out by the plant's ISO supplier. In addition, all expenses related to design costs are included. It can also be mentioned that a full-fledged habitat is a very expensive piece of equipment, e.g. with an estimated cost of approx. 80,000 euros.

The design of the habitat case 100 according to the invention is designed so that it is portable and only depends on working air from an external non-flammable gas and/or air source, such as, but not limited to, e.g. a compressor or an oxygen tank to be able to maintain an overpressure in the habitat case 100. As said, instead of air and/or oxygen, other compressed gases which are not flammable can also be used. In the event of an overpressure in the habitat case 100, a flammable gas from the surroundings will not have the opportunity to enter the habitat case and its ignition source (e.g. a fiber splicing device 110) which is placed inside.

The habitat case 100's simple design and ease of use mean that no additional training is required to be able to use the habitat case 100, but it is pointed out that all procedures for use must be followed up carefully in order to work safely. That is that the person splicing fiber can also operate the habitat case 100 provided that the procedures are followed, and is not dependent on a third party for a full-fledged habitat.

What is unique about this invention is that an elastic material 101 is arranged in a window 101, e.g. in front of a lid 101D to the habitat case 100, which means that a fiber splicing device 110 that is placed inside the habitat case 100 can be operated without any physical buttons. The material of the window 101 can be selected from several types of elastic materials, such as, but not limited to, for example, rubber and/or silicone. The material of the window 101 may further be compatible with touch screens.

The material of the window 101 can be partially or completely transparent in order to be able to see and operate the fiber device 110 located inside the habitat case 100. You physically press the window 101 where you want to operate the device 110 inside the habitat case 100. You do not have to place the device 110 in a specific or indicated position to be able to operate the device thanks to the large and elastic material 101 of the window.

The habitat case 100 is placed horizontally on a workbench/surface. The lid 101D is opened when the habitat case 100 is placed on the workbench/surface. One end of a first hose 105A is connected to a first quick coupling 104A on the habitat case 100. One end of a second hose 105B is connected to a second quick coupling 104B on the habitat case 100. A differential pressure gauge 106 is connected to the other end of the second hose 105B by means of a quick connection to the differential pressure gauge 106. The function of the differential pressure gauge 106 is to control the excess pressure in the habitat case 100. The differential pressure gauge 106 can be analog or digital. The differential pressure gauge 106 measures both the atmospheric pressure outside the habitat case 100 and the internal pressure in the habitat case 100, and the differential pressure is displayed in pascals. A regulator 109 is connected to the other end of the first hose 105A by means of a quick coupling to the regulator 109. An external supply for air and/or at least one non-flammable gas (here, in addition to air, one or several non-flammable gases) are connected via a plug-in nipple 107 which is mounted on the regulator 109. The function of the regulator 109 is to control the pressure coming from the external supply (not shown) for air and/or at least one non-flammable gas, as this is done to control the pressure in the habitat case 100 in order to thereby avoid damage being caused to the material of the window 101, in the form of, for example, excessively high pressure inside the habitat case 100. It can also be ensured that the habitat case 100 is clean inside to avoid dirt and pre-cleaning in connection with fiber splices.

Before use, it can be ensured that the regulator 109 is closed. An external supply (not shown) for air and/or at least one non-flammable gas is connected to the insertion nipple 107. A fiber device 110 is inserted into the habitat case 100. The desired fiber to be spliced is inserted into fiber bushings 102A and 102B, each of the fiber bushings 102A and 102B are arranged on two opposite / opposite walls, e.g. on each short side wall, to the habitat case 100, the distance from corners being the same on both sides. The fiber feedthroughs 102A and 102B are mounted so that one can feed the fiber/fibers directly into the fiber apparatus 110 and to avoid unnecessary bending of the fiber/fibers and potential damage to the fiber/fibers. That is that the fiber feedthroughs 102A and 102B are arranged approx. at the same level as feedthroughs to the indicated fiber apparatus 110. A power supply cable is inserted into a cable feedthrough 102C on the habitat case 100. The lid 101D is closed and locked by means of locks 101E arranged on a wall, e.g. a long side wall, opposite the wall with hinges for the lid 101D of the habitat case 100, and locking brackets 101A arranged on one of the edges, e.g. a long side edge, to the lid 101D. The regulator 109 is carefully opened to let air and/or a non-flammable gas into the habitat case 100, until e.g. approx. 1 bar, as one should keep an eye on a manometer 108. An overpressure or differential pressure must be verified on the differential pressure gauge 106, e.g. max. approx. 50 pascals. Operation of the fiber apparatus 110 takes place through the window made of the elastic material 101, in the lid 101D. The material of the window 101 is elastic, so that the fiber device can be operated without any physical buttons on the case or box. The procedure for using the habitat case 100 is formulated as follows. This consists of several steps to ensure safe use.

The habitat case 100 according to the invention can be constructed of stainless steel, such as, but not limited to, e.g. ss316. It can also be built from other alloys, metals or other hard and strong materials, such as e.g. composite, etc. The habitat case 100 may be rectangular in shape and may be equipped with a lid 101D which is hinged by means of hinges 101B to the habitat case 100, and with locking brackets 101A which are arranged in the one of the edges, e.g. a long side edge, to the lid 101D which is not hinged and which is above the lid 101D edge with the hinges 101B. There is a gasket 101C which is arranged between the edges of the lid 101D and the habitat case 100 itself and which functions as a sealing surface to prevent large pressure drops. The gasket can be made of rubber, silicone or another soft material. The locks 101E which cooperate with the lock brackets 101A on the lid 101 are mounted on a wall, e.g. a long side wall, which lies above the wall with the hinges 101B, (and in front of the habitat case 100). The habitat case 100 can have a handle 101F which can be arranged on e.g. the wall with the locks 101E (and in front of the habitat case 100). The handle 101F can be arranged between the locks 101E. The handle 101F can be used in connection with moving/transporting the habitat case 100. On the habitat case 100, two pieces of cutouts have been made for the fiber feedthroughs 102A and 102B, on two opposite/opposite walls, e.g. on the two short side walls, for the habitat case 100, as well as a cut-out for the cable feed-through for power supply 102C. The lid 101D is hinged 101B, at its edge above the edge with the locking brackets 101A, to the case wall above the wall with the locks 101E and is locked by means of the locking brackets 101A on the lid 101D and the locks 101E on the habitat case 100 wall. The lid 101D has a cut-out or a window located in the middle and provided with an installed flexible / elastic, partially or completely transparent material 101. The material 101 can be attached to the habitat case 100 with (pop) rivets (can also be bolted and/or glued) and perforated flat iron. The perforated flat iron also acts as a clamping/sealing plate to ensure that the elastic material 101 is firmly attached to the lid 101D, as well as to avoid accidental leakage between the lid 101D and the elastic material 101. By perforated flat iron is meant an iron with a pre-drilled hole along the entire surface, e.g. approx. 0.5-1.0 cm between each hole. The elastic material 101 is attached between the perforated flat iron and the lid. It can be mounted e.g. two pieces of ventilation nipples 103 (i.e. at least one ventilation nipple 103) in one of the walls of (e.g. in front of) the habitat case 100, this to ensure air flow in the habitat case 100. Two pieces of plug-in nipples 104A and 104B with quick connectors are mounted in one of the walls of (e.g. in front of) the habitat case 100. From the first insertion nipple 104A, the first hose 105A is connected using the quick coupling that goes to the regulator 109. The regulator 109 has the manometer 108 mounted on it to show pressure from the external gas - or the air supply. The plug-in nipple 107 for connecting the external gas or air supply is also mounted on the regulator 109. From the second insertion nipple 104B, the second hose 105B is connected by means of the quick coupling, the second hose 105B going on to the differential pressure gauge 106. The function of the differential pressure gauge 106 is to ensure and/or verify that there is always overpressure inside the habitat case 100 while it is in use. The fiber and power feedthroughs 102A, 102B and 102C are padded with a brush-like material to ensure that the fiber(s) and cable are not damaged when using the habitat case 100 when the lid 101D is closed.

The habitat case 100 together with all associated equipment, such as, but not limited to, the fiber splicing apparatus 110, the regulator 109 with the manometer 108, the differential pressure gauge 106, the external gas or air supply for air and/or a non-flammable gas, constitute the protection system according to the invention.

Claims (12)

PATENT CLAIMS 1. A habitat case (100) which is approximately cubical or square prism-shaped and which is configured for fiber splicing in a surrounding work area where there is a risk of the presence and/or leakage of a flammable gas, where the habitat case (100) comprises: - a first fiber feedthrough (102A) and a second fiber feedthrough (102B) which are symmetrically arranged on two opposite parallel walls of the habitat case (100) in order to thereby remedy the splicing of two optical fibers which are each inserted into the respective fiber feedthrough (102A, 102B ); - a cable feedthrough (102C) which is arranged on the habitat case (100) and which is configured for power supply to a fiber splicing apparatus which is placed inside the habitat case (100); - a first plug-in nipple (104A) which is arranged on the habitat case (100) and which is configured for connection, via a first hose (105A), to a regulator (109) with a manometer (108) and with a plug-in nipple (107) for connecting an external supply for air and/or a non-flammable gas, the external supply providing for creating and maintaining an overpressure in the habitat case (100); - a second insertion nipple (104B) which is arranged on the habitat case (100) and which is configured for connection to a differential pressure gauge (106) via a second hose (105B); and - a fully or partially transparent window (101) which is arranged on a large wall of the habitat case (100), where the large wall lies between the two opposite walls with the fiber penetrations (102A, 102B) and is perpendicular to these, where the window (101) is made of an elastic material, thereby providing for operation of the fiber splicing apparatus, and where the habitat case (100) further comprises at least one ventilation nipple (103) which is arranged in one of the walls of the habitat case (100), thereby ensuring air flow in the habitat case (100). 2. The habitat case (100) according to claim 1, where a large wall of the habitat case (100) forms a lid (101D) which is provided with hinges (101B) and at least one locking bracket (101A). 3. The habitat case (100) according to claim 2, where the elastic window (101) is arranged on the lid (101D). 4. The habitat case (100) according to claim 2 or 3, where the at least one locking bracket (101A) is configured to cooperate with at least one respective lock (101E) which is arranged on a wall of the habitat case (100). 5. The habitat case (100) according to any one of claims 2-4, further comprising a seal (101C) which is arranged to seal between the edges of the lid (101D) and the respective four wall edges of the habitat case (100) and which functions as a sealing surface to prevent a large pressure drop therein, as the gasket (101C) is made of a soft material, such as, for example, rubber and silicone. 6. The habitat case (100) according to any one of the preceding claims, wherein the penetrations (102A, 102B, 102C) for fiber and cable supply are padded with a brush-shaped material to thereby ensure that fiber and cable are not damaged when using the habitat suitcase (100). 7. The habitat case (100) according to any one of the preceding claims, further comprising a handle (101F) which is arranged on a wall of the habitat case (100). 8. The habitat case (100) according to any one of the preceding claims, where the habitat case (100) is made of one of: stainless steel, alloys, metals and/or other hard and strong materials, such as for example ss316 and composite, thereby being able to withstand the overpressure therein. 9. The habitat case (100) according to any one of the preceding claims, wherein the elastic material of the window (101) is selected from one of: rubber, silicone and/or compatible with touch screens. 10. A protective system configured for fiber splicing in an ambient work area where there is a risk of the presence and/or leakage of a flammable gas, where the system includes: - the habitat case (100) according to any one of the preceding claims; - a fiber splicing apparatus (110) which is placed in the habitat case (100) and which is configured for splicing two optical fibers which have been introduced into the habitat case (100) via the fiber bushings (102A, 102B), the fiber splicing apparatus (110) being supplied with power from an external power source via the cable entry (102C) for power supply; - a regulator (109) which has a manometer (108) and an insertion nipple (107) and which is connected to the habitat case (100) via a first hose (105A); - an external supply for air and/or a non-flammable gas, which external supply is configured for the supply of air and/or a non-flammable gas to the habitat case (100) via the regulator's (109) insertion nipple (107), the external the supply is configured to create and maintain an overpressure in the habitat case (100); and - a differential pressure gauge (106) which is connected to the habitat case (100) via a second hose (105B) and which is configured to ensure and/or verify a differential pressure between the internal excess pressure in the habitat case (100) and the atmospheric pressure outside the habitat case ( 100). 11. The protection system according to claim 10, where the regulator (109) is configured to regulate and/or maintain the excess pressure in the habitat case (100) in the range from approx. 0.1 bar to approx. 2 bar. 12. The protection system according to claim 10 or 11, where the differential pressure gauge (106) is further configured to regulate and/or maintain the differential pressure in a range from about 30 pascal to about 70 pascal.