EP0215966B1

EP0215966B1 - Waste heat recovery installation

Info

Publication number: EP0215966B1
Application number: EP85111559A
Authority: EP
Inventors: Klemens Waterkotte
Original assignee: Klemens Waterkotte
Priority date: 1985-09-12
Filing date: 1985-09-12
Publication date: 1989-12-13

Description

The invention relates to a heat recovery system according to the preamble of claim 1.
In the course of the shortage of raw materials, more and more efforts have been made in recent years to make better use of the reserves that still exist. Recycling measures mean that substances that were previously written off as waste are reused. However, this recycling does not find its limits in the reprocessing of valuable substances. So one has also started to use the energy reserves more economically. The significantly improved heat pumps have made it possible to use previously unused heat sources, e.g. geothermal energy for heating e.g. To use living and office space. These systems are also suitable for the production of hot domestic water. Conversely, households and, to a large extent, industry also produce warm water, which was drained into the sewage system in previous years. It made sense to look for processes that could at least partially recover this energy lost per se. Another reason for extracting heat from this wastewater is that the warm wastewater places too much stress on our rivers and lakes, which heat up and the habitats of some animals and plants become smaller and smaller, while others multiply uncontrollably.
DE-OS 26 25 157 describes a system for heat recovery from wastewater in which a collecting tank is switched on between a wastewater channel and a central wastewater pipe. In the outlet of this container, a gate valve is arranged, which is connected to a temperature sensor. The outlet is shut off at a specified wastewater temperature. A heat exchanger is arranged in the tank and is connected to one or more storage tanks which are connected upstream of hot water consumers or heaters. In the event that the storage tanks are upstream of a room heating, the publication suggests raising the water temperature in the storage tanks by means of a heat pump.
However, the construction of such a system is complicated and expensive. Nevertheless, the efficiency is rather low, since the medium to be cooled is directly applied to the heat exchanger, which is known to result in a not very good heat transfer.
The invention is therefore based on the object of designing a heat recovery system of the type mentioned at the outset in such a way that, despite its simple construction, a greater heat transfer factor and thus better efficiency are achieved.
The invention solves this problem with the help of the features of claim 1. Further advantageous embodiments of the invention are the subject of the dependent claims.
In the system according to the invention, a vacuum pump ensures a negative pressure in the container. When the motorized valve is open, the warm waste water flows through the step filter into the tank until the liquid level has reached the upper switch. This closes the engine valve. Since the liquid enters an evacuated room, the contents of the vessel are in a saturated steam state. If the heat pump is now switched on, the evaporator cools down. The saturated vapor cuts off on the evaporator and condenses. The heat transfer from condensing steam to the surface of the evaporator is particularly favorable. The heat transfer coefficient of condensed water vapor on a metal wall is a = 10,500 kW / m 2 / K, while for boiling water it is only a = 3,500 to 5,834 and for still water it is only a = 350 to 584. The evaporator can be designed as a smooth tube coil, finned tube coil or as a lamella cooler. By transferring heat to the evaporator, the liquid in the container cools down. If the temperature falls below a certain level, the pump is switched on and liquid is pumped out of the container until the liquid level reaches the lower float switch. This switches off the pump and opens the motor valve so that new wastewater can flow in. If the target temperature has not yet been reached when the upper float switch is reached, the pump is switched on again until the level of the lower switch is reached and waste water can flow in via the valve that opens again. The heat pump is connected directly upstream of the heat consumer or heater. The construction according to the invention makes it possible to dispense with the previously known complicated control and the interposition of storage containers, since the container according to the invention takes on both the function of the collection container and the storage container.
If, as proposed in claim 2, the supply of the waste water is designed as a ring line, the openings of which are arranged above the upper switch and point obliquely downwards towards the inner wall of the container, it is possible to rinse the inner wall through the waste water, so that tastings caused by impurities still contained in the waste water can be avoided.
In order to prevent excessive foam formation when the waste water flows in, or to prevent the foam from coming into contact with the evaporator, which would reduce the heat transfer factor, a foam breaker is arranged between the upper switch and the evaporator. This foam breaker also prevents the entrainment of liquid particles, which would also adversely affect the heat transfer factor. Such foam breakers can e.g. consist of wire mesh mats arranged one above the other.
According to claim 4, the pump is connected to the filter via a line. The pumped-out liquid rinses the filter contaminated by the inflowing water. To the pumped liquid to regulate the quantity, there is a throttle valve behind the pump.
To control the fill level, a sight glass is provided in the container wall according to claim 5. For maintenance and inspection work in the container, this has a lockable manhole.
According to claim 6, a drip tray is arranged in the container below the evaporator, which is connected via a vacuum lock to a collecting container arranged outside the container. This makes it possible to collect the relatively clean condensate and possibly to carry it out for analysis, since easily boiling components such as gasoline or alcohol accumulate in the condensate.
To protect the vacuum pump, a cold trap is provided in the suction line from the container to the vacuum pump, which ensures that the pump is not unnecessarily burdened by the suction of saturated steam. This protection is particularly important when the vacuum pump is switched to continuous operation. However, it is also conceivable, particularly in the case of larger systems, to provide control of the vacuum by means of a pressostat, so that the pump only has to be started up temporarily.
An embodiment of the invention is illustrated and explained in the following with the aid of a drawing. The heat recovery system shown in the drawing has a container 1 which is connected at its top by a line 2 to a vacuum pump 3. A cold trap 4 is arranged in line 2 between container 1 and vacuum pump 3. A line 5 opens into the underside of the container 1 and serves to supply the waste heat-carrying waste water into the container. A line filter 6 is installed in the line 5 outside the container 1 and a motor valve 7 is installed between the stage filter 6 and the container 1. The underside of the container 1 has a further opening 8, from which a line 9 extends, which leads to a pump 10 and from the pump 10 to the line 5, where it opens between the motor valve 7 and the step filter 6. In front of the mouth there is a throttle valve 11 in line 9. Approximately in the middle of the container 1, an upper float switch 12 and a lower float switch 13 are arranged in the wall of the container 1 at a certain distance from one another. The line 5 rises in the container 1 to a level that lies above the switch 12. There the line 5 opens into a ring line 14 which is guided horizontally along the inner wall of the container 1. The ring line 14 has a plurality of openings 15 which are directed downwards onto the inner wall of the container. Above the ring line 14, a foam crusher 16 is arranged horizontally over the entire cross section of the container 1, e.g. can consist of wire mesh mats arranged one above the other. In the upper area of the container 1 there is an evaporator 17, which consists of a smooth tube coil, a finned tube coil but can also be designed as a lamella cooler. The evaporator 17 is connected in a circuit to a heat pump 20 by means of lines 18 and 19. The heat pump 20 can e.g. be designed as a compression or absorption heat pump, but other types are also possible; in the case of a compression heat pump, it consists of a compressor 21, a condenser 22 and a refrigerant collector 23, which flow in the direction of flow from the evaporator 17 and flow in the lines 18 and 19 Refrigerant are arranged one behind the other. The flow of the refrigerant can be interrupted with the help of the valve 24. The cold trap 4 is also connected to the heat pump 20 via the lines 25 and 26, the line 25 also being able to be shut off via a valve 27. A drip tray 28 is arranged below the evaporator 17 and is connected to a collecting container 30 outside the container 1 via a vacuum lock 29 (shown in dashed lines). At the level of the switches 12 and 13, a sight glass 31 is arranged in the wall of the container 1 and beneath it a manhole 33 which can be closed with a cover 32. Below the switch 13, a temperature sensor 34 is arranged in the housing wall, which extends into the waste water liquid. The temperature sensor 34 is electrically connected to the pump 10. The switch 12 is electrically connected to the engine valve 7 and the switch 13 is electrically connected to both the engine valve 7 and the pump 10. The electrical connections are not shown for better clarity of the drawing. The switches 12 and 13 are designed so that the switch 12 floats with rising liquid level and switches off when a certain height is reached. The switch 13 switches off when the liquid level drops when the buoyancy body of the switch arm in the liquid reaches a certain height.
The operation of the system is described below:
The waste heat-carrying liquid is passed through line 5 into the ring line 14 via the filter 6 and the open motor valve 7. It leaves the ring line 14 via the openings 15 and flows down the inner wall of the container 1, in which a vacuum was created with the aid of the vacuum pump 3. The space above the rising liquid level is thus in the saturated steam state. The foam breaker 16 prevents the foam which forms during the outflow of the liquid from rising up to the evaporator 17, as well as any liquid particles. The vapor phase strikes the evaporator 17, which has cooled down by actuating the heat pump 20, condenses there and condenses. As a result, the refrigerant flowing in the evaporator heat pump circuit is heated and transported to the heat pump 20, which uses the heat to heat, for example, service water. The liquid in the container 1 is extracted more and more heat and it cools down. When the temperature reaches a certain lower value, the pump 10 is switched on, which draws liquid from the container 1, which is drained through the filter 6 for rinsing. Reaches the liquid mirror the level of the switch 13, the pump 10 is switched off and the motor valve 7 is switched on. Waste heat-carrying waste water flows via the ring line 14 into the container until the level has reached the switch 12. The engine valve 7 is closed. If the temperature in the liquid is still too low, the pump 10 is switched on again and so on.
The distillate dripping from the evaporator 17 can be collected in the tub 28, passed through the vacuum lock 29 to the collecting container 30 and examined there.

Claims

1. A waste heat recovery installation for waste heat conducting liquids such as sewerage, whereby the liquid is conducted to a container (1) provided with a temperature sensor (34), in which a heat exchanger (17) is arranged which is connected to a heat pump (20), characterized in that the container (1) can be evacuated by means of a vacuum pump (3), that the liquid can be introduced through a pipe (5) by way of a filter (6) and a motor-driven valve (7) over a pipe (5) into the container (1) in which two floating switches (12, 13) are arranged one above the other, of which the upper switch (12) serves for closing and the lower switch (13) for opening the valve (7), that the sensor (34) arranged in the container (1) for measuring the temperature of the liquid is electrically connected to a pump (10) which serves for lowering the liquid level in the container (1) and which can be switched by means of the lower switch (13), and that the heat exchanger (17) is a vaporizer arranged above the upper switch (12) which is connected by way of pipes containing coolant (18, 19) to the heat pump (20).

2. A waste heat recovery installation according to claim 1, characterized in that the pipe (5) for the liquid is a tube projecting above the height of the upper switch (12) which is connected by its upper end to a closed circular pipe (14) which extends around the inner wall of the container, which is provided with apertures (15) which are inclined downwardly towards the inner wall of the container.

3. A waste heat recovery installation according to claim 1 or 2, characterized in that between the vaporizer (17) and the upper switch (12) there is provided a foam breaker in the form of wire grid mats arranged on top of one another.

4. A waste heat recovery installation according to one of claims 1 to 3, characterized in that the pump (10) is connected to the filter (6) by way of a pipe (9, 5) and a regulating valve is arranged between the pump (10) and the filter (6).

5. A waste heat recovery installation according to one of claims 1 to 4, characterized in that a viewing glass (31) is provided in the wall of the container such as a manhole (33) which can be closed by a cover (32).

6. A waste heat recovery installation according to one of claims 1 to 5, characterized in that a droplet collecting trough (28) is arranged in the container (1) between the upper switch (12) and the vaporizer (17), which is connected via a vacuum sluice (29) to a storage tank (30) arranged outside the container (1).

7. A waste heat recovery installation according to one of claims 1 to 6, characterized in that in the pipe (2) between the vacuum pump (3) and the container (1) a condensation trap (4) is arranged which is connected by way of pipes (25, 26) to the heat pump (20).

8. A waste heat recovery installation according to one of claims 1 to 7, characterized in that the vacuum is controllable by means of a push button.