NL1036368C2 - DEVICE FOR CLEANING SMOKE GAS. - Google Patents

Description

Device for cleaning flue gas.

The present invention relates to a device for recovering CO2 present in a flue gas.

In the state of the art, for example, heat and power plants are used in horticulture, natural gas being used for driving a generator, for example. This generator generates electricity and as further products, heat and CO2 are released. The heat generated can be used to heat a growing space such as greenhouses, while CO2 acts as a growth promoter for certain crops. The electricity can be used for the lighting of cultivation areas and / or can be supplied back to the electricity grid.

The use of CO2 for promoting the growth of certain crops is particularly interesting. However, it has been found that in addition to CO2 also hydrocarbons (such as ethylene) and nitrogen compounds (such as NOx) are present which are found to be toxic by certain crops.

To avoid this problem, filter installations are used in which the gas is passed through channels in which harmful substances are bound by chemical reactions. The installation and maintenance of such filters is expensive and in these installations harmful substances are only partially removed so that the CO2 generated in this way is only used for less sensitive crops and the use in closed greenhouses is less attractive. As an alternative, improved installations have been proposed which, however, are much more expensive to use.

GB 855543 discloses a flue gas cleaning installation operating at elevated pressure. When various substances are added, flue gases are passed through columns at elevated pressure and temperature. Such a device is particularly suitable in the chemical industry.

The object of the present invention is to provide a cultivation system consisting of a cultivation space in combination with an electricity generating generator, wherein said generator is fired with a fossil fuel and the flue gases can be used in the cultivation space.

This object is achieved with a cultivation system comprising a cultivation space with crops disposed therein and a heat and electricity generating generator with a CCb delivery line leading into said cultivation space, wherein the flue gas discharge from said generator comprises a device for the recovering CO2 present in a flue gas comprising a flue gas channel connected to the supply of the flue gas to be cleaned, wherein a water spray system is present, said flue gas channel comprising a water discharge and gas discharge, said water discharge being connected to a closed separation vessel and to said separation vessel being water circulating means connected, which provide for pressure reduction of the water circulating through it and wherein said separating vessel is connected via a return line to said water spraying system and at the top of said separating vessel there is a gas discharge for CO2 emerging from said separating vessel and the gas discharge of the separating solid with said CO2 - supply line is connected.

According to the present invention, the gas from a combined heat and power plant is subjected to a water spray. It has surprisingly been found that the CO2 is absorbed into the water with a sufficient supply of water spray, while NOx and hydrocarbon-containing vapors such as ethylene are absorbed much less. As a result, the water flow from the water spray system comprises substantially pure CO2. Subsequently, this water containing CO2 is supplied to a separation vessel and pressure is lowered in or near this separation vessel. As a result of this pressure reduction, the CO2 is released and rises to the top of the separation vessel and can then be supplied to the cultivation space. A number of separation vessels may possibly be present which may be connected in series.

This system works at a relatively low pressure such as ??? Moreover, the temperature will also be relatively low.

With the present invention it is possible to design a combined heat and power generator more easily. After all, in the state of the art the efficiency of such generators fired primarily on natural gas is increased by cooling the emerging flue gas in a first step and subsequently condensing it.

According to the present invention, such a capacitor is not necessary because the water spraying system described above provides for a reduction in the temperature of the flue gas such that a separate condensing step is not necessary. In addition to CO2, the generator will generate electricity and (cooling) heat. These can be used in the growing room, supplied to households or have a different application.

3

According to a further advantageous embodiment of the invention, an induction-operated device is arranged in the return line between the separation vessel and water spray system. The use of a coil is mentioned as an example in which the water is subjected to an electromagnetic field due to a varying frequency. It has been found that, as a result of changing physical properties of the water, CO2 present in the flue gas can be absorbed in large quantities and subsequently released into a separation vessel.

In principle, contact of water with the flue gases can take place in any way. This makes it possible to spray water in a room.

According to a special embodiment of the invention, the flue gas channel in which the spraying of water vapor takes place is built up from a number of tubes or pipes arranged next to each other. A number of water sprayers is present in each pipe or pipe. The drain for both water and gas can be common to each of these tubes or pipes. The system described above can work with the use of a single or multiple pumps. These use relatively little energy so that large quantities of water can be circulated at a low cost. As a result, a considerable amount of CO2 can be absorbed and released.

Moreover, the sprinkling of the gas that flows through the tubes or pipes 20 has the advantage that residual heat present in the flue gas is absorbed by the water. It is possible to give this heat a further useful use with the aid of heat exchangers. This further increases the energy efficiency of the device. Moreover, more water vapor condenses from the flue gas, which further improves the efficiency.

The water circulation means provide for atomization of the water and for the reduction of the pressure of the water. In principle, a simple pump could be used in which, at the suction side, the CO2 contained therein releases the CO2 contained therein by the underpressure prevailing there. According to a special embodiment of the invention, this effect can be further improved by providing a venturi in the water circulation means. As a result, the water is compressed and expanded, whereby CO2 is released during expansion. This system can be further perfected by connecting a gas pipe in the narrowed part of the venturi. More specifically, this gas line is either connected to the environment (air supply from 4 inside or outside) or to the upper part of the separation vessel through which air is supplied to it. This promotes the release of CO2. According to a special embodiment, water turbulence generating means may be present. More in particular, they may be present as a vane or the like in / for the venturi.

As a result, the efficiency of the release of CO2 increases.

According to a special embodiment of the invention, a substance is added to the water for separating substances which are absorbed into the water and which are not desirable. An example of this is titanium dioxide for the neutralization of NO and NO2 with the aid of UV light.

It is, of course, possible to filter the CO2 released in the path from the separation vessel to the location of use with any filter known in the art.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the drawing. In the drawing: FIG. 1 schematically a cultivation system according to the present invention;

FIG. 2 the separating vessel according to the present invention in more detail;

FIG. 3 a detail of the water circulation means; and

FIG. 4 is a variant of the device shown in FIG.

The cultivation system according to the present invention is indicated in its entirety in FIG. 1 by 1. This consists of a greenhouse 30 or other cultivation space known in the state of the art and a combined heat and power plant indicated by 2. In this example, the combined heat and power plant works on gas that is supplied via line 3, but other fuels can of course be used. Heat, electricity and flue gases are generated in the combined heat and power plant. The electricity is discharged via line 28, the heat via line 27 and the flue gases via outlet 5.

Because it is desirable to recover the CO2 present in the flue gases for use in the cultivation space 30, complicated and expensive cleaning installations have been proposed in the prior art. The present invention has for its object to provide an inexpensive working device for purifying the gases from outlet 5. This device is indicated in its entirety by 4. Outlet 5 leads to a number of flue gas channels 6 arranged next to each other. These have a length of, for example, approximately 20 meters and consist of a plastic material. These can be commercially available tubes with, for example, a diameter of a few tens of 5 centimeters. In each flue gas channel 6 a number of water nozzles 7 is present fed from a pipe 9. The flue gas channels 6 are arranged slightly inclined so that the water emerging from the nozzles 7 flows in the direction of the water outlet 11 which is common to all flue gas channels 6. Also a common 5 flue gas outlet 8 present. (This can also be individual).

A number of separating vessels 12 connected in series are arranged, which for example have a volume of tens of cubic meters. Water outlet 11 comes out in the first of these vessels 12 and is delivered via outlet 34 to inlet 35 of the next vessel. In the example, the mouth of drain 11 or inlet 10 is shown at the top of each vessel 12, but it is also possible to connect water drain 11 or inlet 35 to separation vessel 12 at another location. An amount of water is present in each separation vessel 12, the top of the water level being indicated by 13. Moreover, there is a circulation system 14 in each separation vessel which will be described in detail below. The separation vessels 12 are coupled to each other on both the bottom and the top. Above the water level 13 there is CO2-rich gas which is supplied via the downstream switched vessels to a common pipe 23 and a fan 24 and subsequently to a pipe which blows the CO2-rich gas into greenhouse 30.

The vessels 12 are also in communication with line 9 in which a pump 10 is present. With the aid of separation vessel 12, line 9, pump 10, flue gas channels 6 and water discharge 11, a closed system for the circulation of water is created.

The water present in the separation vessels 12 can be circulated via pipes 22 connected thereto. Each of these conduits has a heat exchanger 31 and the heat derived therefrom is used via a conduit 32 in a manner not further illustrated for, for example, heating a cultivation room or other system.

The electricity line from the combined heat and power plant is connected to lighting 26 located in the growing area. Excess electricity can be supplied to the network via line 33. Heat is supplied via line 27 to a heat exchanger 30 present in cultivation area 30.

Figures 2 and 3 show details of the separation vessel and circulation system 14, respectively. This shows that each water circulation system 14 consists of a pump 15 and a venturi connected before or after it. The venturi 6 has an inlet 17 and an outlet 18 and between them is a narrowed part 19. In this narrowed part under which pressure prevails, one or more openings 20 come out which are connected to a pipe 21 which in this example is connected to the space above water level 13.

The gas purification device described above works as follows:

Flue gas originating from cogeneration plant 2 that contains CO2, NOX) hydrocarbons such as ethylene, is fed via line 5 to flue gas channels 6. There, some contact with water takes place through the water spraying from sprayer 7. In this, mainly CO2 is included and NOx and hydrocarbons are not included. These disappear via flue gas outlet 8. The flue gas is then cooled by spraying, that is to say, water present therein condenses. As a result, the circulating water used for spraying is heated. A downstream condenser in the flue gas outlet is therefore no longer necessary. The water comprising the highest possible proportion of CO2 is supplied via line 11 to the separation vessels 12. This is then brought into circulation with the circulation system 14. Due to the underpressure occurring at venturi 16, water and CO2 separation will occur. This process is further enhanced by the supply of a gas via line 21. The CO2 released rises through the water and is above water level 13 and can be supplied to a cultivation space 20 in the manner described above. By subjecting the flue gas to a water spray, the water will absorb heat and this can be recovered at the heat exchangers 31 for further useful use.

Fig. 4 shows a further variant of the invention which largely corresponds to what is shown in Fig. 1 and is therefore provided with the same reference numerals.

However, in line 9 a device is shown which is indicated in its entirety by 85 and which consists of a magnetic field generating coil 86 which is arranged near or around the line 9 and a frequency inverter 87. By controlling the coil 86 with varying frequency controller 87 has shown that the backflowing water is brought into such a condition that during spraying other undesirable substances such as NOx or sulfur compounds can be included in addition to a better absorption of CO2. If a relatively clean fuel is used, the increase in the 7 CO 2 uptake by the sprayed water is particularly important. This extra absorbed CO2 is then released into the various separation vessels.

After reading the above, those skilled in the art will immediately come up with variants that are within the scope of the present claims. It is thus possible to apply the cleaning to other installations, i.e. not or only partially in combination with a cultivation space. Naturally, any type of crop can be grown in the growing area, such as algae. Moreover, it is possible to use further filters or cleaning installations. Moreover, due to turbulence-increasing means, separation of water and CO2 can be further promoted.

1036368

Claims (16)

1. Cultivation system comprising a cultivation space with crops arranged therein and a heat and electricity generating generator with a CfV delivery line leading into said cultivation space 5, wherein the flue gas discharge from said generator comprises a device for extracting CO2 present in a flue gas comprising a supply of the flue gas duct to be cleaned, in which a water spraying system is present, said flue gas duct (6) comprising a water outlet (11) and gas outlet (8), said water outlet being connected to a closed separation vessel (12) and water circulation means (14) to said separation vessel ) are connected, which provide for pressure reduction of the water circulating through it and wherein said separating vessel is connected via a return line to said water spraying system and at the top of said separating vessel there is a gas discharge for CO2 emerging from said separating vessel and the gas discharge of the separating solid with that CO2 delivery line far is bound. Cultivation system according to claim 1, wherein said flue gas channel is designed for low pressure. 20 Cultivation system according to claim 1 or 2, wherein said cultivation space is provided with lighting supplied with electricity generated by said generator. 4. Cultivation system according to one of the preceding claims, wherein said cultivation space 25 is provided with heating, fed with heat generated by said generator. 5. Cultivation system according to one of the preceding claims, wherein said flue gas channel comprises a number of pipes connected in parallel to each other with a length of at least 5 m. 30 The cultivation system according to claim 5, wherein said pipes open onto a common water drain and gas drain. 1036368 7. Cultivation system according to one of the preceding claims, wherein said connection between the separation vessel and water spray system comprises a pump. 8. Cultivation system according to any of the preceding claims, wherein said water circulation means have both the inlet and the outlet in said separation vessel. 9. Cultivation system as claimed in any of the foregoing claims, wherein pressure reduction in the water circulation means is provided by a venturi construction. The cultivation system of claim 9, wherein the venturi structure comprises a water inlet and a water outlet separated by a narrowed portion. 11. Cultivation system according to claim 10, wherein said constricted part comprises a gas supply. Device as claimed in claim 11, wherein said gas supply is connected to an air supply line. 20 Device as claimed in any of the foregoing claims, wherein water turbulence generating means are connected to said separation vessel. 14. Device as claimed in any of the foregoing claims, comprising means for supplying polluting gases binding substances to that water. Device as claimed in any of the foregoing claims, wherein a number of separation vessels are arranged in series. Cultivation system according to one of the preceding claims, wherein an electromagnetic device (85) is arranged in said return line (9), said electromagnetic device (85) having an induction coil (86) and a voltage source (87) with varying frequency for controlling which includes induction coil. 1036368