NO167176B - HOUSE DISTRIBUTION NETWORK FOR SINGLE AND COMMON ANTENNA SYSTEMS. - Google Patents

Abstract

In a home signal distribution network for individual and community antenna systems for the joint reception of the terrestrial audio and television broadcast programmes and one left-hand and one right-hand polarised DBS television programme each, two transmission lines are provided for separately supplying in each case two antenna sockets per subscriber connection point, in which arrangement the left-hand polarised DBS television signals are transmitted on one transmission line and the right-hand polarised DBS television signals are transmitted on the other transmission line in the first satellite intermediate-frequency band and each antenna socket has two outlets. In this home signal distribution network, terrestrial broadcast signals are also transmitted in both transmission lines, one outlet of the antenna sockets fed from the transmission line for the left-hand polarised DBS television signals being provided for receiving the terrestrial broadcast signals and the other outlet of the antenna sockets fed from the transmission line for the right-hand polarised DBS television signals being provided for the reception of the terrestrial television broadcast signals. As a result, the home signal distribution network can be set up, produced and installed in an electrically and mechanically simple and inexpensive manner, whilst having good transmission characteristics. <IMAGE>

Description

Adsorption column.

The present invention relates to an adsorption column for separating at least one component in a gas stream from the other components by adsorption on a suitable adsorption material. More particularly, the invention relates to an improved substrate for a layer of solid adsorption material in an adsorption column.

A construction which is widely used in various chemical processes, and especially in the refining of mineral oils, is an adsorption column or container which usually comprises an elongated, usually cylindrical chamber containing a solid material which is capable of adsorbing a selected component from a gas mixture which passes through the column. The column will of course usually contain conduits or supply openings for introducing the gas mixture at one end of the column and for removing at least part of the gas mixture from the other end of the column after it has passed through the filling of adsorption material.

The container or chamber which delimits the solid adsorption material can meanwhile be quite large, and the mass or weight of the adsorption material in the container then becomes correspondingly large. A strong base structure is therefore necessary at the bottom of the container to support the adsorption filling and in the meantime problems arise by preventing the solid adsorption material from clogging or choking the outlet lines that lead into the bottom of the columns that contain large amounts of the adsorption material.

A problem that also often occurs when operating such adsorption columns at high temperatures during the extraction of hydrocarbons or other materials from very hot vapors or gases is that the thermal variations that can occur inside the column, from time to time result in high mechanical stresses which acts in welding summer, connections and couplings in wires and

rudder as a result of expansion and contraction of the connected parts. These stresses can be of considerable magnitude and cause cracks in the summer or breaks in connections and couplings so that gases passing through the column can leak out, parts of the adsorption material can be lost or other damage can occur, necessitating disconnection of the column from the process and dismantling of it for a longer period of time in order to repair the damage that has occurred in this way. One of the most frequently occurring defective connections as a result of thermally induced stresses is the connection between outlet lines from the adsorption column and the plate or substrate that lies below and supports the layer of adsorption material.

The present invention provides a new and improved substrate structure for the layer of solid adsorption material used in the adsorption column, which substrate structure is particularly well suited for use in adsorption columns of relatively large size and which from time to time work under high

temperature conditions, where the column has the opportunity to

cooled between such operations.

The invention is thus based on an adsorption column comprising an oblong container containing a solid adsorption material, as well as a base structure for the solid adsorption material, which base structure comprises a number of gas-receiving containers spaced around a centrally located branching container and arranged at the lower end of the column. The peculiarity of this column is that the base construction, in addition to the gas-receiving containers and the branching container, which containers have open gas-receiving upper ends, includes: a layer of compressible, heat-insulating material around the sides and bottom of each container; grates and fine mesh screens, placed above the grates, across the open upper ends of each container for supporting the solid adsorbent material; manifolds which connect the gas-receiving containers with the central container and which, in a manner known per se, slideably extend into the respective containers to compensate for thermally conditioned changes in position of the containers; as well as a gas outlet conduit extending slidably out of the central container and out through the lower end of the column; and a fixed pluggable insulating material placed at the lower end of the column around the containers, the rudders and the heat insulating material, the pluggable insulating material projecting up to the horizontal plane through the upper ends of the containers.

Adsorption columns constructed in accordance with the invention can withstand greater thermal stresses caused by interrupted operation of the column at high temperatures without causing leaks or unwanted cracks in summer or connections. The effective operating life of the column is significantly extended and the extent of necessary maintenance and the resulting dbd time for the columns is significantly reduced.

From the preceding description of the invention, it will be understood that the present invention provides a new adsorption column construction which contains an improved substrate for the adsorption layer which, without malfunctioning, is able to withstand operation of the column

over a wide temperature range over longer periods of time.

Another advantage of the invention is that it provides a relatively cheap substrate structure for the adsorption material for use in an adsorption column, which substrate structure is relatively simple mechanically and is easy to build and repair when necessary.

Other advantages of the invention will be understood from the following detailed description of it seen in connection with the accompanying drawings illustrating the invention. Fig. 1 is an elevation of the adsorption column constructed according to the present invention.

Fig. 2 is a section taken along line 2-2 in fig. 1.

Fig. 3 is a section taken transversely through the adsorption column along the line 3-3 as shown in fig. 1. Fig. h is a section through the adsorption column taken along the line k-h in fig. 1.

Fig. 5 is a section along the line 5-5 in fig. 2.

Fig. 6 is a perspective view of the diffuser device mounted at the top of the adsorption column according to the invention.

Fig. 7 is a section along the line 7-7 in fig. 6.

In the individual drawings and especially in fig. 1, an adsorption column manufactured according to the present invention is generally denoted by the reference number 10 and comprises an elongated, largely cylindrical retainer? or mantle 12. The cylindrical mantle 12

is supported by a largely cylindrical base 1^- which can be designed in one with the mantle 12 or be extended as shown in fig. 2 as a separate cylindrical part which is welded or in some other suitable way attached to the casing 12. In the construction shown, the cylindrical casing 12 is closed by means of concave upper and lower

end parts, respectively 16 and 18. The bottom end part 18 of the mantle 12 lies at a distance above a bottom plate 20 in the base 1<*>f, and a suitable access opening 21 is arranged in the vertical side wall of the base.

The cylindrical mantle 12 is lined with a suitable pluggable insulating material, generally denoted by the reference number 22. By a pluggable material is meant here a refractory material added

a binder and arranged to be stopped in place and set to a solid state. A typical example is a suitable mixture of Portland cement and powdered perlite which can be used as stop material in the adsorption column according to the invention. The pluggable material can be placed on the inside of the jacket 12 in any suitable way, such as e.g. by spraying with a plaster gun,

and is held in place by means of suitable concrete reinforcing metal wire mesh 2k which is stretched between studs 26 projecting inwards from the cylindrical shell 12.

As will best be seen from fig. 1, the concave upper end part 16 of the cylindrical casing 12 is provided with a flanged, gas inlet pipe 30 and a manhole 32 which facilitates access to the interior of the column. At the lower end 1 of the cylindrical mantle 12 there is arranged a cleaning hatch 3*+ for the purpose of being able to remove the solid adsorption material in the column if desired. As will best be seen from fig. 5, the cleaning hatch 3^ comprises a short rudder part 36 which protrudes from the cylindrical casing 12 and slidably encloses a plug 38 of the pluggable material which fits sealingly into a complementary opening through the pluggable material 22 which is arranged as a lining on the casing 12. suitable handles hO are provided to facilitate the removal of the plug 38 of pluggable material, and a blind flange h2 is attached by means of bolts hh to a circumferential flange ^6 welded to the rudder 36. When the blind flange k-2 is removed from the circumferential flange h6, the plug can of pluggable material 38 is withdrawn to provide access to the interior of the column 10 so as to adsorb the ionic material. may be removed from there.

Hanging down from the concave "upper end part 16 of the column 10 at

with the help of four support rods h-8 and placed immediately below the gas inlet 30, a diffuser device 50 is arranged, which is shown in detail in fig. 6 and 7 and comprises three angle iron supports 52 which extend

itself between the supporting rods kQ and forms a three-sided trough for supporting a perforated horizontal diffuser plate $+. Perforated side diffuser plates 56 rest on the horizontal top edges of the angle iron supports 52 and extend between the four support rods kS. It should be noted that the angle iron is omitted on one side of the diffuser arrangement 50 so that the horizontal diffuser plate 5k can slide into place on the three angle irons 52 from the side of the diffuser arrangement facing the manhole 32.

Across the adsorption column 10 at a level below the diffuser device 50 is arranged a distribution trough 60, which comprises a plurality of sections of grates 62 which are bolted together in the composite form shown in fig. 2 and h using matching, vertically protruding knobs 6h. The composite grating sections 62 are supported in the adsorption column 10 on a pair of horizontally extending support rails or rods 66 each of which is bolted to the lower ends of a pair of vertical rods 68 which in turn are welded or otherwise suitably attached at their upper ends to the concave upper end part of the mantle 12. One of the grid sections, which is denoted by the reference number 62a in fig. <*>f, is placed between the horizontal support rods 66 and directly below the manhole 32, so that it can be removed to enable access from the top of the adsorption column to its interior under the distribution trough 60.

At the lower end of the adsorption column 10, the substrate construction 70 is placed to support the filling or made of adsorption material that is placed inside the column. The underlay construction 70 comprises a number of gas-receiving reservoirs or containers 72 which are placed in a largely circular arrangement around a centrally located branching container 7h.

In the shown embodiment of the invention, the collecting containers 72 and the branching container 7h are cylindrical and are provided with disc-shaped gratings 76 which extend over the top of them. A relatively fine-mesh screen 78 covers each of the respective grates 76. Each of the gas collection containers 72 in the circular arrangement is attached to and supported by the concave bottom part 18 by means of angle supports 79.

Through and radially outward from the side of the branching container 7<*>+

a plurality of collecting lines 80 are arranged which mutually connect the branching container 7^ with each of the collection containers 72 placed in a circle around the branching container. The busbars

80 extends through the side wall in each of the collection containers and it will be noted with reference to fig. 2 that each of the lines 80 is somewhat longer than the distance between each of the gas collection containers 72 and the branching container Jh. The headers 80 are slidably placed through the walls of the respective gas collection containers 72 and the branching container 7^ instead of being rigidly attached thereto for purposes which will be described later. Each conduit 80 carries a pair of spaced weld beads 82 which limit the sliding movement of the conduit between its respective gas collection vessel 72 and the branch vessel Jh. All the containers and the bus lines 80 are sheathed or coated

with a sleeve of compressible, thermally insulating material 8>+, such as e.g. fiberglass, with a thickness of around 13 mm. As will be understood with reference to fig. 2, however, the open upper ends of the container remain exposed and are not covered with fiberglass.

After the so far described substrate 70 for the adsorption material is mounted, the stoppable material 22 is placed under and on the sides of the containers 72 and 7^ and around the conduits 80 up to the level of the open upper ends of the containers as shown in fig. 2. A gas ButlopsLine 85 extends slideably through the bottom of the branching container 7^ °6 extends through and is welded to the concave lower end part 18 of the mantle 12. The upper end of the gas outlet line 85 is provided with a movement-limiting cuff 86 which is placed in distance from a circumferential flange 88 attached around the conduit to limit the sliding movement of the empty conduit relative to the branch receptacle 7^. Below the concave end part 18 of the mantle 12, the gas discharge line 85 is bent at an angle of 90° to extend horizontally through the side wall of the cylindrical base 1^-. A suitable gas outlet fitting 90 is attached to the end of the gas outlet line 85 outside the adsorption column 10. This part of the line 85 between the lower end part 18 and the branch vessel 7^ is also sheathed with a compressible, heat-insulating material such as e.g. fiberglass.

When building the adsorption column 10, first the substrate construction 70 for the adsorption material is assembled at the bottom of the column by workers who have entered the column through the manhole 32. With the gas collection containers 72, the branching container 7^5 and interconnected lines 80 and the gas outlet line 85 in place and enveloped in glass fiber insulation as described, the stoppable material 22 is then placed on the inside of the column wall by stope or spray technique in a manner known per se. The rods hQ and 68 for supporting the diffuser device 50, respectively. the distribution trough 60 has naturally been attached to the metallic, concave upper closing part 16 for the application of the stoppable material. The various grate sections 62 in the distribution trough 60 are then bolted in place over, and supported by, the support rods 66, with the exception of the fall dor section 62a in the grate construction. The mounts can then pass through the opening left for the fall dor section 62a in the distribution trough 60 and out through the manhole 32. The horizontal perforated diffuser plate 5^ can be inserted into the diffuser device 50 by feeding it through the manhole 32. The adsorption filling for the column 10, which can typically be pelletized, activated carbon, can be introduced into the column for placing the fallback 62a in place, so that the column is completely filled by the layer of 1 adsorption material from the substrate structure 70 up to the distribution trough 60. When the filling of the column is completed, the falldor section 62a in the distribution trough 60 is inserted through the manhole 32 and bolted in place to complete the assembly of the column.

When the column 10 has been connected to the gas stream which it is desirable to subject to treatment in the adsorption column, the gas flows in through the inlet 30 and is distributed radially in the column by means of the diffuser device 50. It is further evenly distributed for passage through the layer of adsorption material by using the distribution trough 60. After passing through the entire layer of adsorption material, the gas flows into the gas collection containers 72 and the branching container 7^. The gas flows from the collection containers 72 through the collecting lines 80 and into the branching container 7^5 and from this the gas is removed from the column 10 via the gas outlet line 85-

Over longer periods of operation followed by, or preceding, cessation of operation, the metal elements in the underlying structure 70

exposed to significant variations in ambient temperature and therefore undergoes noticeable expansion and contraction. Such expansion and contraction is accommodated by the new embodiment of the base construction 70 according to the present invention in that the metallic parts in the construction are slidably fitted into each other and separated from the stoppable material by means of compressible glass fibers. Thus, when the containers 72, 7^ and/or the lines 80 undergo expansion or contraction, no significant stress is exerted on the stoppable material 22 which surrounds these elements due to the intervening glass fiber insulation or sheathing 8h. Furthermore, the development of hot spots in particular places on the metallic containers 72 and 7*+ or the collecting lines 80 is avoided due to the thermal insulation effect of the glass fiber layer. Finally, it enables the fact that the collecting lines 80 and the gas outlet line 85 are slidable,

rather than rigidly connected to their respective containers, that these elements can expand or contract without causing cracks or breaks in the containers or unwanted cracks in permanent, rigid connections or couplings.

It will be understood from the preceding description of the invention

that a new and very applicable adsorption column is proposed by the present invention, which column is distinguished by a longer and relatively more disturbance-free operating time than has been the case with previous column constructions of this type. Furthermore, the way in which the column is constructed enables easier operation and easier maintenance and that the adsorption material in the column can be changed more quickly.

Claims (1)

Adsorption column comprising an oblong container (12) containing a solid adsorption material, as well as a base structure for the solid adsorption material, which base structure (70) comprises a number of gas-receiving containers (72) arranged at a distance from each other around a centrally located branching container (7<*>0 and arranged at the lower end of the column (10), characterized in that the base construction (70) in addition to the gas-receiving containers (72) and the branching container (7<*>+), which containers have open gas-receiving upper ends, comprises : a layer of compressible heat-insulating material (8*+)-around the sides and bottom of each container (72.7*0; grates (76) and fine-mesh screens (78), placed above the grates, across the open, upper ends of each container for supporting the solid adsorption material; collection lines (80) which connect the gas-receiving containers (72) with the central container (7<*>0 °g which, in a manner known per se, slideably extends into in the respective - containers to compensate for thermally conditioned positional changes of the containers; as well as a gas outlet line (85) which slides out of the central container (7<>>+) and out through the lower end of the column (10); and a fixed stoppable insulating material (22) placed at the lower end of the column around the containers (72,7<*>+), the rudders (80,85) and the heat insulating material (8<*>+), the stoppable, insulating material projects up to the horizontal plane through the upper ends of the containers (72.7^).