FR2864911A1 - Liquid and gas separator for condensing heat exchanger has chamber with chicane between mixture inlet and gas outlet - Google Patents

Abstract

A separator, comprising a chamber (8) with an inlet for the liquid/gas mixture, a lower outlet (18) for the liquid and an upper outlet (17) for the gas, has a chicane (19) between the inlet and gas outlet that causes the mixture to flow round its edge (24) that is furthest from the gas outlet. A separator, comprising a chamber (8) with an inlet for the liquid/gas mixture, a lower outlet (18) for the liquid and an upper outlet (17) for the gas, has a chicane (19) between the inlet and gas outlet that causes the mixture to flow round its edge (24) that is furthest from the gas outlet. The gas outlet is located at the top of the chamber's front wall (14) inside the upper end of the chicane, and the liquid outlet is located in the chamber base and offset towards the front wall. The chicane has an upper surface that is inclined downwards towards the edge (24) that the flow turns round, the edge having an upturned lip (26).

Description

Description

  The present invention relates to a liquid-gas separation device.

  The present invention also relates to a heat exchanger thus equipped, including a condenser-type exchanger having the effect of condensing certain constituents of an initial gas mixture and thus producing a two-phase mixture whose liquid and gaseous phases must then be separated.

  Gravity separators with or without a recovery device are known for trapping droplets in the gas outlet.

  Cyclone separators are also known.

  These devices are bulky and usually result in recovering the gas at the top and the liquid at the bottom. They therefore impose congestion and installation constraints. In addition, they inherently have a relatively high pressure drop.

  For heat exchangers of the vertical flow condenser type, it is possible for the gas stream to rise while the condensate droplets fall into a lower tank as they form. This arrangement has the disadvantage that the rising gas flow tends to cause some of the droplets with him in the upper outlet for the gas flow.

  In the downward gas flow exchangers, the droplets can only go in the right direction, that is to say downwards, but then there is the problem of separating the liquids and the gases at the bottom of the exchanger, with the problem mentioned above with regard to the disadvantages of current separators.

  The object of the present invention is thus to provide a liquid-gas separation device for, from a two-phase fluid, separating the liquid and the gas in a minimum of volume and with a reduced pressure drop, as well as a heat exchanger equipped with such a device.

  According to the invention, the liquid-gas separation device comprising a vessel having a two-phase mixing inlet, a lower liquid outlet and an upper gas outlet, is characterized in that a baffle placed between said inlet of the mixture in part high of the tank and the gas outlet defines for the flow a lobe bypassing a detour edge of the baffle, away from the gas outlet.

  The baffle according to the invention directly receives droplets which strike it and then form a flow towards the bottom of the tank. On the other hand, the lobed path of the flow projects other droplets against the side wall of the tank and to the bottom thereof, by centrifugal effect.

  After the turn, precipitation of the droplets may still occur before the flow reaches the gas outlet.

  Dynamic separation is therefore achieved by extremely simple means and in a particularly small space.

  According to a second aspect of the invention, the heat exchanger comprising a box in which are arranged separate paths for two exchange fluids, is characterized in that this box is closed at the bottom by the tank of a device of liquid-gas separation according to the first aspect.

  Other features and advantages of the invention will emerge from the description below, relating to a non-limiting example.

  In the accompanying drawings: - Figure 1 is a schematic view of an exchanger according to the invention with tearing, in elevation; - Figure 2 is a top view of the separator device of the exchanger according to Figure 1; Figure 3 is a perspective view of the separating device; and - Figure 4 is a side elevational view of the separation device.

  In the heat exchanger 1 shown in FIG. 1, a gaseous flow 2 which must be partially condensed follows a vertical path descending inside a caisson 3 constituted in this example by a rectangular or square section tube forming a conduit vertical flow 2. The box has an open top end connected to a junction box 4 through which the flow 2, and an open bottom end 6 whose periphery is connected contiguously with the rectangular periphery 7 (FIG. 2) of the open top of a tank 8 forming part of the separation device 9 which will be described in detail below. In a manner that is only very schematically represented, there is in the box 3 a path 11 for a heat extracting fluid. The path 11 is sealingly separated from the space reserved for the flow 2. In practice, the path may in known manner be constituted by one or more tubes, or by plates defining inside their cavities for the circulation. calorie extracting fluid, or second fluid. The walls separating the path 11 relative to the flow 2 serve at the same time as heat exchange walls through which the second fluid extracts heat from the flow 2, which produces the condensation of certain components of the flow 2 Thus, when it enters the tank 8, the flow 2 is two-phase, that is, it comprises droplets entrained by the gas flow.

  The separation device 9 will now be described in more detail.

  The tank 8 has a half-cylinder shape with a horizontal axis, open upward to form the inlet opening 10 of the two-phase mixture 22 in the horizontal axial plane surrounded by the connecting edge 7 with the box 3. The opening is total and therefore delimited by the connecting edge 7. The vessel 8 comprises a semi-circular profile wall defining two side walls 12 joined in a continuous manner by a bottom 13, and a front end wall 14 and a rear end wall 16, each in the form of a half plane disk. Two opposite sides of the periphery 7 are defined by the two ends of the half-circle profile wall defining the side walls 12 and the bottom 13. The two other opposite sides, front and rear respectively, of the periphery 7 are constituted by the two upper edges of the front walls 14 and respectively rear 16. The semicircular periphery of the front walls 14 and respectively rear 16 is sealed to a respective one of the semicircular edges of the semi-circular profile wall defining walls 12 and the bottom 13.

  The front wall 14 of the tank 8 is traversed by an outlet 17 for the separated gases. This outlet is placed on the median vertical axis of the front wall 14 at a short distance below the periphery 7. The bottom 13 is crossed by an outlet 18 for the separated liquid. The outlet 18 is located near the front wall 14 and in the lowest zone of the bottom 13.

  According to the invention, a baffle 19 is placed between the inlet 10 of the mixture in the tank 8, formed by the open top of the tank 8, and the gas outlet 17. In particular, the baffle 19 has a front edge 21 which is welded against the inside face of the front wall 14 of the tank 8 so as to prevent the two-phase flow 22 (FIG. 4) entering the tank 8 from directly accessing the gas outlet 17. the baffle 19 defines to the flow 22 a lobe 23 (Figure 4) bypassing a detour edge 24 of the baffle 19, opposite the edge 21 welded to the front wall 14. The edge 24 is located at a distance from the inner face of the rear wall 16.

  The baffle 19 has a downward slope towards the detour edge 24. This slope is indicated by the angle Al in FIG. 4. The angel A1 is preferably between 5 and 30. The detour edge 24 has a spoiler 26 directed upwards to prevent the liquid streaming on the baffle 19 from forming, beyond the detour edge 24, a cascade that would be captured by the gas flow and entrained towards the gas outlet 17. .

  However, the spoiler 26 is interrupted at each of its ends near the semi-cylindrical wall of the tank to provide runoff passages 27 along the side walls 12 and / or the bottom 13, on either side of the tank. gaseous flow.

  In the example shown, the baffle shown is in the form of a dihedral with a central longitudinal line of apex 28, on either side of which the baffle 19 has a downward slope indicated in Figure 1 by an angle A2 which is preferably less than or equal to 30. The gas outlet 17 is located just below the top 28 of the baffle 19. The lateral edges 29 of the baffle are welded along their entire length to the semi-cylindrical inner face of the tank and thus form with said inner face a gutter 31 of liquid runoff to the passages 27 on either side of the spoiler 26.

  The length LL (FIG. 3) of the vessel measured along the periphery 7 of its upper opening 10 parallel to the plane of the lobe 23 formed by the flow, thus parallel to the length of the baffle 19, may be between 500 and 4000 mm.

  The width LA measured in the plane of the upper opening 10 of the vessel 8 perpendicular to the plane of the lobe 23 is also between 500 and 4000 mm. The shape of the upper side of the bowl 8 may be rectangular, square or of another shape, and the width may be greater than the length or vice versa. The length LC of the baffle 19, measured horizontally and parallel to the length LL, thus parallel to the plane of the lobe 23, is preferably between 0.5 LL and 0.7 LL. The maximum height H of the tank is less than or equal to the smaller of the two values LL and LA. The level X (FIG. 1) of the lower edge of the gas outlet 17 is greater than or equal to the level Y of the highest point of the detour edge 24.

  The liquid outlet 18 is preferably sized so that the flow velocity of the liquid is less than about 0.5 m / s.

  The operation of the separation device is as follows, with reference to FIG. 4.

  In a first zone Z1 located just after the inlet 10 of the flow 22 in the tank 8, droplets contained in the portion of the flow located above the baffle 19 are deposited by gravity on the baffle 19, flow on the baffle 19 and then on the inner wall of the tank through the passages 27. This flow of runoff thus arrives at the bottom 13 of the tank to leave it by the departure of liquid 18. In the zone Z2 corresponding to the turn lobe 23, other droplets are projected by centrifugation to the rear wall 16 and to the bottom 13 of the tank.

  In the zone Z3 located under the baffle 19, the gas flow rises towards the outlet 17 while the droplets that it still contains fall by gravity towards the bottom 13 of the tank to leave it by the liquid outlet 18, or even strike the front wall 14 below the gas outlet 17 to fall towards the bottom 13 of the tank.

  Of course, the invention is not limited to the example described depicted.

  It can be imagined that the tank is extended rearwardly beyond the opening 10 of communication with the caisson 3 and that the baffle 19 extends to below the rear edge of the inlet opening 10 of the diphasic mixture. . Thus in zone Z1, even the droplets contained in the most posterior part of the flow 22 would have an opportunity to be deposited on the baffle in zone Z1. The lobe 23, and more particularly the zone Z2, would be in a region where the top of the tank is closed.

Claims (14)

  A liquid-gas separation device comprising a tank (8) having a two-phase mixing inlet (10) (22), a lower liquid outlet (18) and an upper gas outlet (17), characterized in that a baffle (19) placed between the inlet (10) of the mixture in the upper part of the tank and the gas outlet (17) defines for the flow a lobe (23) bypassing a detour edge (24) of the baffle (19), away from the gas outlet (17) 2. Device according to claim 1, characterized in that the gas outlet (17) is placed on a front wall (14) of the tank (8).   3. Device according to claim 1, characterized in that the liquid outlet (18) is placed in the bottom (13) of the tank (8) in a manner offset to a side (14) where the outlet is located. of gas (17).   4. Device according to one of claims 1 to 3, characterized in that the baffle has a downward slope (Al) to the detour edge (24).   5. Device according to one of claims 1 to 4, characterized in that the detour edge (24) has a spoiler (26) directed upwards.   6. Device according to claim 5, characterized in that the spoiler (26) is interrupted to provide at least one runoff passage (27) near an inner face of the vessel (8).   7. Device according to one of claims 1 to 5, characterized by at least one runoff passage (27) for the separated liquid, adjacent to the baffle (19) and an inner face of the vessel.   8. Device according to one of claims 1 to 7, characterized in that the baffle (19) has a lateral inclination (A2).   9. Device according to one of claims 1 to 7, characterized in that the baffle (19) has two lateral inclinations (A2), each of an apex (28) of the baffle (19) to a side wall (12). ) of the tank (8).   10. Device according to claim 9, characterized in that the gas outlet (17) is under the top (28) of the baffle (19) 11. Device according to one of claims 1 to 10, characterized in that the inlet of the mixture (10) is constituted by the open top of the tank.   12. Device according to one of claims 1 to 11, characterized in that there is provided a runoff gutter (31) formed at the junction between at least one side edge (29) of the baffle (19) and a wall (12) corresponding to the tank (8).   13. Device according to one of claims 1 to 12, characterized in that the vessel (8) has in the horizontal plane a length (LL) and a width (LA) both between 500 mm and 4000 mm.   14. Heat exchanger comprising a box (3) in which are arranged separate paths for two exchange fluids, characterized in that this box (3) is closed at the bottom by the tank (8) of a separating device liquid gas (9) according to one of claims 1 to 13.