SE430184B - PROCEDURE FOR THE WASTE WATER RECOVERY AND THE IMPLEMENTATION PROCEDURE - Google Patents

Description

7908805-9 2 b! '_11 40 the exchanger 14 is a strainer connected to the line 12. example with reference to the drawing.

Fig. 1 shows a plan of how a plant according to the find can be connected to a sewer line, Fig. 2 shows schematically the plant from the side in cut condition, Fig. 3 shows it in the plant including the heat exchanger in section, Fig. 4 shows the heat exchanger the exchanger according to Fig. 3 seen from above, Fig. 5 shows a part of a detail included in the heat exchanger and Fig. 6 shows a part of the plant with four series-connected heat exchangers. 7 In Fig. 1, 1 denotes a building, for example one hospital, and 2 the from this going sewer. From line Z runs a branch line 3 to a pump station 4, which via a line 5 pumps the wastewater to the heat recovery the extraction plant S according to the invention. From heat recovery the extraction plant 6, the heat-drained sewage the water to the line 2 via a line 7. The part of the the line Z which lies between the branch lines 3 and 7 acts as a shunt line and is fitted with a valve, S0m at the plant's operation is normally closed. It from the wastewater recovered heat energy, for example in the form of hot water, transported to the consumer, the hospital building 1, via nings 8. 7 To the heat recovery plant, as schematically shown in Fig. Z, is pumped via the pump station 4-wastewater through the line 5 into the top of a waste water tank 9, which at the bottom is connected to the line 7 for the cooled wastewater discharge through the sewer line 2. At the bottom in the cistern 9 a level pipe 10 is connected, which is connected with the line 7, in which further between the cistern and the level the pipe a valve ll is arranged. When the valve 11 is closed the wastewater surface in the cistern will thus be located 'at the height of the level pipe bend. Ytnívân is denoted by 37. From the upper part of the tank 9 drains the incoming, "hot", the wastewater, which may have a temperature equal to about 30 ~ L0 ° C during the day, via a line 12 to a heat exchanger 14, which will be described later. The heat energy in sewage _ the water is discharged in the heat exchanger 14 to the pipe arranged therein. loops 15, after which the wastewater from the heat exchanger flows back to the cistern 9 through a line 13, which opens into the bottom area of the cistern, as shown in the figure.

To prevent solid contaminants from being led to heat Sílen 16 har 7908805 -0 the shape of a cylindrical basket, the cylinder surface being a screen mesh extending above the liquid surface 37. 17 denotes nozzle-mounted arms designed to rotate a center axis. To clean the screen, lower the liquid surface cistern 9, by opening the valve 11, and flushing therewith after the strainer using the rotating nozzles that are fed with flushing nut via line 18. The contaminants stuck on the outside of the sieve net is then flushed loose and sinks to the cistern 9 bottom. This cleaning of the screen net is conveniently done at regular time intervals, for example at 24 hour intervals, whereby at the same time emptying of sludge, which has accumulated on the bottom of the cistern, takes place via the valve 11.

As a heat-absorbing medium in the heat exchanger 14 pipe loops 15 are used in the case shown here water, which in the example is stored in a water reservoir 19. Cold water is led from the bottom area of the magazine via line 20 to the heating exchanger 14, in which the water is heated by the waste water and is led to the upper area of the magazine 19 via the line 21.

To the water reservoir 19 is further a heat pump 22 with evaporator 23 and condenser 24 connected, so that the hot water at the top in the magazine via the line 25 emits its heat energy to the the steamer 23, to be returned to the bottom area of the magazine, in which the cooled water is located. 43 denotes one circulation pump, 26 denotes an electric motor with compressor and 27 denotes the outgoing and incoming lines to the circulation the circuit for the heat pump's heat carrier, ie. for the medium heated by the wastewater (and by it to the compressor supplied energy) and to be used for consumption and / or heating purposes. This medium can, for example vuavmïm.

In order not to disturb it in the tank and the magazine the stratification between cold bottom water and hot surface water is, as shown in Fig. 2, the outlets from the pipes , 21 and 26 extended by diffusers 28, through which velocities the heat on the effluent is reduced as much as possible.

The magazine 19 serves as a buffer during the time that the energy supply through the wastewater is low, for example at night, by having the magazine have a volume to store sufficient hot water to supply the heat pump below this time. 40 v9osàos-0 Following the above description of the principle for the plant according to the invention, of which description even if the function of the system is clearly stated, the heat exchanger shall 14 are touched on in more detail.

I 7 Without a well-functioning heat exchanger does not work either the plant why the design of the heat exchanger must be considered as a critical part of the whole system. out 1 The heat exchanger 14 shown consists of a housing 29 with a central channel 30. Concentric in the house and in relation to each other a number of heat exchange surfaces are arranged, which each consists of a number of parallel-connected pipe loops (Figs. 3 and 5 show 20 pieces). The ends of those in one "surface packages" including the pipes 15 are connected to a common divider 32, by means of which the heating medium, in this case the water, begins in the pipe loops 15, and to a common receiver 33 by means of which the water is collected and diverted from the package. As It can be seen from the figures that the circulation pump 34 pumps the water via the conduit 20 and the manifold 32 into the tubing loops thereof the first package 15. The water is led from it via the receiver 33 the first packet through a connection line 35 to the internal for the horizontal package distributor 32 '(Fig. 4). From this package receiver 33 ', the water is passed on to the third the package via a line 35 'and distributor 32 ". From this third package receiver 33 "directs the water to the fourth-H the package via line 35 "and distributor 32" '. From the fourth the receiver 33 "'of the package is led to the water via line 21 the upper part of the magazine 19.

Between the concentrically arranged heat exchanger packages are arranged likewise concentrically arranged partitions 36, which abut at the bottom against the bottom of the heat exchanger housing and extends above level 37 of the waste water in the heating the exchanger. The conduit 12 from the cistern 9 opens into the interior the compartment of the heat exchanger, ie. between the inner wall of the house (duct wall 30) and the innermost partition wall 36. the water is diverted from the heat exchanger via line 13, connected to the outermost compartment of the heat exchanger, as shown in Fig. 3 and 4. At the bottom of the partitions 36, openings 37 are provided, in the case shown along a radius towards the outlet 13.

From the above it appears that the heat absorption the water flows through the series-connected heat exchanger loops, k; (Il s 79084805-0 from the outermost package to the innermost, while the the water, the heat of which is to be extracted, flows from the innermost the chamber to the outermost via the openings 37. The energy exchange thus takes place according to the countercurrent principle, whereby wastewater ~ the temperature drops abruptly from compartment to compartment while the water the temperature in the loops rises after a curved curve.

At the top of the heat exchanger a rotatable arm 38 is arranged driven by a motor 39 via a shaft 40, which runs through the housing 29 central channel 30. The arm and shaft are mounted on the conventional and not shown manner. The arm 38 is provided with vertically directed brushes 41, see Fig. 3, whose bristles on rotation of the arm cover the pipe loops 15. This keeps the surfaces of the pipe loops clean. As as can be clearly seen from Fig. Z, the plant shown is completely "open" and the surface of the waste water in the cistern 9 and in the heating the exchanger 14 to be at the same level 37. That of the wastewater circulation through the heat exchanger 14 necessary pump power obtained by the rotation of the arm and thus the movement of the brushes in chambers, in principle there is a very slow working circulation pump. The speed of the wastewater flow through the heat exchanger can be regulated by means of the speed of the arm 38 and / or a valve 42 in the outlet of the heat exchanger, see Fig. 4.

The brushes 41 are replaceable and easily accessible from top of the heat exchanger.

Pig. Z shows the plant in a simple design, ie. with a cistern 9, a heat exchanger 14 and a magazine 19 but it is of course possible to connect several of them in parallel system or that instead of one have several heat exchangers connected to a cistern and a magazine.

I To reduce the size of the heat exchanger can several smaller heat exchangers are connected in series with each other, while maintaining the countercurrent principle.

I fig. 6 shows four heat exchangers each basically the same as the one described. The resp. of heat exchangers 43 heat exchanger surfaces 44 are connected in series with each other via 45, with the supply line 20 for the heating medium and íranloppsledníngen 21. The wastewater flows from the cistern 9 via the line 12 in countercurrent through the heat exchangers, as thus are connected to each other via the pipes 46 for the wastewater.

In such cases, continuous wastewater flows 7908895-eva t 6 of magazine 19, connected to heating heating medium can is not necessary to use but can the heat-absorbing water directly pump evaporator. Instead of water like others in the art and commonly used heaters. the medium is used.

Claims (1)

7 7908805-o Patent Claim _. A method for heat recovery from waste water, characterized in that the waste water is led into a collecting part (9), diverted from its upper part to a heat exchanger unit (14) from which the cooled waste water is led into the lower part of the collecting part (9). ), from which the lower part of the waste water is diverted, that the heating medium circulating in the heat exchanger unit (14), heated by the waste water, is led to the evaporator (23) of a heat pump, and then back to the heat exchanger unit (14). Z. A method according to claim 1, characterized in that the heating medium from the heat exchanger unit (14) is led to the upper part of a magazine (19) and that the heating medium after heat pump evaporator (23) is led to the lower part of the magazine (19). Method according to claim 1 or 2, characterized in that the heating medium is conducted concentrically in the heat exchanger unit (14) internally arranged, mainly cylindrical jacket-shaped heat exchanger surfaces (15), starting from the outer surface, and that the heating medium led from the innermost surface to the evaporator (23) and that the waste water is led to flow around the heat exchange surfaces (15) starting from the innermost surface and that the waste water is led from the area of the outer surface to the collecting part (9). 4. System for heat recovery from waste water, characterized by a cistern (9) with a supply line (5) for waste water and an outlet arranged for the connection of the waste water to a drain (7) at the bottom of the cistern (9), a heat exchanger unit (14), a line (12) connecting this to the upper part of the cistern (9) for hot wastewater transport to the heat exchanger unit (14) and a line (13) connecting the cistern to the waste water transport from the heat exchanger unit to the cistern, in the heat exchanger unit (14). loops (15) arranged for a heat medium in the wastewater which absorbs the circulating heating medium, a heating medium heated by the waste water to a evaporator (23) conducting pipe system (21, 25) and an evaporator (23) connecting the pipe system (23) to the loops (15). Z6, 20) for heat medium cooled in the evaporator, the evaporator being included in a heat pump (22). A plant according to claim 4, characterized in that the heat exchanger unit (14) consists of at least one heat exchanger comprising a cylindrical housing (29) having concentrically and at a distance therein spaced apart and communicating cylindrical heat exchanger surfaces (15), concentric between these arranged walls (36), the conduit (12) for hot wastewater transport to the heat exchanger (14) opening in the area of the innermost heat exchanger surface in the housing_and the conduit (13) for transporting the waste water to the tank (9) connects to the radially outer part of the housing and wherein the conduit system (21, 25) for heated heating medium is connected to the innermost heat exchanger surface and the conduit system (26, 20) for cooled heating medium is connected to the outer outer heat exchanger surface. Plant according to claim 5, characterized in that the cylindrical housing (29) is arranged so that its axis is vertical and that the heat exchanger surfaces (15) covering cleaning means (41) are arranged extending in the axial axis of the housing. direction from a support member rotatable about the axis (38). Plant according to claim 6, characterized in that the tank (9) and the heat exchanger unit (14) together form communicating vessels and that the circulation of the waste water through the heat exchanger unit (14) is effected by the movement of the cleaning means. Plant according to one of Claims 4 to 7, characterized in that the outlet of the cistern (9) is connected to a level pipe (10) which opens into the drain (7), which forms a gap between the level pipe and the bottom of the cistern. valve-mounted (11) shunt line no. A system according to any one of claims 4 - 8, characterized in that the conduit system for heated heating medium consists of a first conduit (21), which opens into the upper part of a magazine (19), from which upper part a second conduit (25) leads to the evaporator (23) and that the conduit system for cooled heating medium consists of a third conduit (26) which from the evaporator (23) opens into the lower part of the magazine (19), from which lower part a fourth conduit (20) leads to the heat exchanger 1 unit_ (14). Plant according to claim 9, characterized in that the first and second lines (21, 25) open into a first common, upwardly directed diffuser (8), the mouth of which is located in the vicinity of the liquid level surface in the magazine (19). ), and that the third and fourth lines (26, 20) open into a second common, downwardly directed diffuser (28) whose mouth is located near the bottom of the magazine (19). Plant according to one of Claims 4 to 10, characterized in that the pipe (12) for hot waste water is connected to a silk basket (16) arranged in the upper part of the tank (9) and extending above the waste water surface and in that the pipe ( 13) for the transport of the waste water from the heat exchanger unit (14) to the cistern (9) opens into a downwardly directed diffuser (28), the mouth of which is located near the bottom of the cistern. Plant according to one of Claims 5 to 11, characterized in that the heat exchanger unit consists of two or more heat exchangers (43), the heat exchanger surfaces (44) of which are connected in series (45) with one another and which heat exchangers are connected in series (46) with respect to the waste water. flow through the heat exchangers. 79088 05 ~ 0