PL232868B1 - Device for sequential cleaning and recovery of heat from waste gases emitted from a chimney - Google Patents

Abstract

The device for sequential purification and heat recovery from exhaust gases imitated from a chimney consists of a device housing (2) mounted on the chimney (1), in which there is a flue gas discharge section (A) and a flue gas purification section (B). In the exhaust gas cleaning section (B), on the outlet side there is a fan (3), a filter (4) and a sprinkler of the absorption solution with a buffer substance (5), under which there is a liquid tank (6), which is connected to the heat exchanger (7). ), which in turn is connected via the liquid regeneration device (8) to the sprinkler of the absorption solution with the buffer substance (5). A cylindrical ceramic foam filter (9) is partially immersed in the liquid tank (6), the upper part of which covers the inlet from the exhaust gas discharge section (A) to the exhaust gas treatment section (B). The cylindrical-shaped ceramic foam filter (9) is connected in its axis perpendicular to the direction of exhaust gas flow to the engine drive shaft (10).

Description

Description of the invention

The subject of the invention is a device for sequential cleaning and heat recovery from the flue gases emitted from the chimney, especially from the chimney of a boiler room or a domestic heating furnace.

Various types of devices for cleaning exhaust gases in chimneys are known to date. In these devices, most often aerosol particles on various types of filtering materials are removed from the exhaust gas. Then, filters for the exhaust gas pre-treatment are distinguished, whose task is to separate coarser aerosol particles from the exhaust gas. There are also fine and final filters for cleaning exhaust gases from submicrometer particles.

In the patent application WO2009011685 (A), a filter device is disclosed for purifying the exhaust gases discharged through a stack. The device consists of a chamber placed on the chimney with an inlet and outlet exhaust, in which there is a replaceable or recyclable ceramic filter cartridge.

From the patent specification US8083574 (B1) there is known an exhaust gas cleaning device in the form of an attachment to the outlet of the exhaust gas discharge pipe. This cap is equipped with a replaceable catalytic filter that cleans the exhaust gases passing through it.

In addition to filtration devices, devices for inertial, centrifugal and electrostatic exhaust gas cleaning are also known. These can be devices in which the flue gas is cleaned with both dry and wet methods. From the patent specification US9084964 (B1) there is known a device for exhaust gas cleaning consisting of a dry scrubber and a radial fabric filter and a centrally located axial fan which forces the exhaust gas to flow. From the description of the utility model CN201200847 (Y) a device is known in which a multi-stage wet exhaust gas purification is carried out. The device consists of series-connected dust collectors equipped with water sprinklers. The exhaust gases, which are forced to move by a fan, pass successively through the individual dust collectors and are gradually cleaned. In the description of the patent application CN106871147 (A) there is presented a device for cleaning exhaust gases discharged from a coal boiler, consisting of an element forcing the exhaust gas, a water mist diffusing element and a filter element. A similar device that can be installed on a flue gas chimney is presented in the description of the utility model application CN206027343 (U). The exhaust gases in this solution pass through the water layer and are subjected to double purification in the filters.

Various types of cyclone dust collectors are widely used devices for exhaust gas cleaning, which use the effect of centrifugal forces on pollutant particles. An example is the device for dedusting exhaust gases and industrial gases described in the patent description PL216644 (B1).

Electrostatic flue gas cleaning is carried out in electrostatic precipitators. Exemplary solutions for the construction of electrostatic precipitators are presented in the patents DE1078096 (B) and EP2451582 (B1). US6621136 (B2) discloses an electrostatic dust collector having a central high voltage electrode and a porous material disposed therein to trap charged aerosol particles. The patent application US3400513 (A) presents an electrostatic dust collector made in the form of a channel reducer resembling a jet pump. The device described in the patent application US3222848 (A) has interchangeable frames with collecting electrodes, which are cleaned after a certain time of device operation. On the other hand, the patent specification US6783575 (B2) shows an electrostatic filter installed inside the exhaust gas channel.

There are also known solutions that use the properties of ionized matter. The device described in the patent application CN106731544 (A) comprises a chamber through which exhaust gases pass and in which a fabric filter for removing particulate matter is installed at the exhaust inlet. In the center of the chamber there are one or more plasma reactors, whose task is to clean the exhaust gases from chemical impurities, and at least one fan is installed at the chamber outlet. The device equipped with gas burners, whose task is to burn off solid particles and other flammable substances contained in the exhaust gas, is presented in the application for utility model CN206073093 (U). Patent application CN106322408 (A) describes a catalytic combustion device which comprises a combustion chamber, a heat exchanger, an exhaust gas filter and a fan, the exhaust gas filter being downstream of the heat exchanger.

Devices using photocatalytic oxidation processes are also known. In the patent description US7951327 (B2) a photocatalytic air pollutant removal module is presented. The main element of the device is a filter with a filter cloth coated with TiO2 and an activating one

UV lamp. The patent application US20040007453 (A1) shows an air purifier with a cylindrical shape, inside which a UV lamp is placed, illuminating specially shaped fibers covered with a photocatalytic substance. A photocatalytic device in which elements with surfaces covered with a photocatalytic material and UV light sources are arranged concentrically along the contaminated gas flow path is presented in the patent application US20100209312 (A1).

Exhaust gas treatment can be performed in devices in which various cleaning methods are combined in various combinations. For example, exhaust gas dedusting can be carried out in devices where inertial forces, centrifugal forces and electrostatic forces act simultaneously on the dirt particles. In the solution disclosed in the patent description PL194549 (B1), the pollutant particles are separated from the exhaust gas in a device having a cylindrical porous partition, a centrally located lower particle removal channel and an upper channel for discharging purified exhaust gas. From the patent description PL216297 (B1) there is known a device for centrifugal purification of exhaust gases with a structure similar to a cyclone separator. The device has an electrode generating corona discharges and concentrically arranged vertical louvers acting as discharge electrodes.

Various types of devices for recovering heat from the flue gas discharged through a chimney are known. From the patent application WO9701072 (A1) a heat exchanger is known, which is mounted on a conduit discharging exhaust gases from the combustion chamber. The factor collecting heat from the exhaust gas is circulated to the partition through which the exhaust gases pass. In the patent description PL195174 (B1) a heat exchanger is presented, which in the outer layer has helically mounted pipes through which the medium that receives heat from the flue gas flows. A heat recovery device that can be mounted in two-channel chimneys is described in the patent description PL200318 (B1). The internal channel is used to discharge the flue gas, while the external channel is used for the medium collecting heat from the flue gas. Patent application CN106322408 (A) describes a catalytic combustion device which comprises a combustion chamber, a heat exchanger, an exhaust gas filter and a fan, the exhaust gas filter being downstream of the heat exchanger.

The aim of the invention is to sequentially purify and recover heat from the flue gases emitted from the chimney, especially from the chimney of a boiler room or domestic heating furnace.

The essence of the device for the sequential purification and heat recovery of the exhaust gases emitted from the chimney, which has a fan and the exhaust gas purification filter, is that the housing of the device mounted on the chimney includes an exhaust gas discharge section and an exhaust gas cleaning section. In the flue gas cleaning section there is a fan on the outlet side, as well as a filter and a sprinkler for absorption solution with a buffer substance, under which there is a liquid tank, which is connected to a heat exchanger, which in turn is connected through a liquid regenerating device with a sprinkler of absorption solution with a buffer substance . The cylinder-shaped ceramic foam filter is partially immersed in the liquid reservoir, the upper part of which covers the inlet from the exhaust gas discharge section to the exhaust gas cleaning section. The cylinder-shaped ceramic foam filter is connected in its axis perpendicular to the direction of exhaust gas flow with the drive shaft of the engine. Preferably, the surfaces of the cylindrical ceramic foam filter are coated with a catalytic substance. The first exhaust gas temperature and pressure sensors are located in the exhaust gas section, as well as the first sensors for the concentration of aerosol particles and chemical pollutants. In the exhaust gas cleaning section, between the fan and the filter, there are second sensors of exhaust gas temperature and pressure and second sensors for the concentration of aerosol particles and chemical pollutants. The exhaust gas temperature and pressure sensors as well as the concentration sensors for aerosol particles and chemical pollutants are connected to a control module connected to the fan. Preferably, the fan and the control module are connected to a voltage converter which is connected to the power module. Preferably, the power module is connected to the photovoltaic panel which is fixed to the chimney or to the housing of the device through a mechanism controlling its position.

The advantageous effect of the application of the invention is that at low investment and operating costs, harmful pollutants are removed from the flue gases emitted from the chimney and heat is recovered. Regardless of the quality of the fuel to be burned and the efficiency of the combustion process, which can be improved using the recovered heat, the quality of the exhaust fumes is acceptable. Treatment of exhaust gases related to the so-called low emissions from the chimneys of local boiler houses and domestic heating stoves significantly reduces the possibility of smog formation. Recovered heat

The use of flue gases in the heating system increases the energy efficiency of the building.

The invention is illustrated in an exemplary embodiment in a perspective view of the drawing of the device.

The device for sequential cleaning and heat recovery from the flue gas emitted from the chimney presented in the example in the drawing was mounted on the chimney 1, the rectangular cross-section of which had dimensions of 0.20 x 0.27 m. The housing of the device 2 contained a flue gas discharge section A and a section purifying flue gases B. In the flue gas cleaning section B, a fan 3 was installed, under which there was a GREENLINE filter 4 by PSG SYSTEMS and a sprinkler for the absorption solution with a buffer substance 5, and under them there was a liquid tank 6. A Systemair ZRS 180 steel fan was used stainless steel with a maximum flow rate 518 m ³ / h. An aqueous solution of calcium chloride with a buffer substance, Absorben 75, was used as the absorption solution. The liquid tank 6 was connected to a heat exchanger 7, which was a WP 6/6 capacitive exchanger by PROFIL. This exchanger was connected through a liquid regeneration device 8 with a spray of absorption solution with a buffer substance 5. In a liquid regeneration device 8 in the form of an oxidizing centrifuge reactor, the precipitated calcium sulphate (gypsum) and the remaining absorbed impurities were removed from the liquid. The cylinder-shaped ceramic foam filter 9 from Ferro-Therm with a porosity of 30 ppi was partially submerged in the liquid contained in the liquid reservoir 6. Its upper part covered the inlet from the exhaust gas section A to the exhaust gas cleaning section B. The axis of this filter was perpendicular to the direction of the exhaust gas flow and was connected to the drive shaft of the engine 10. The surfaces of the cylinder-shaped ceramic foam filter 9 were covered with a photocatalytic substance based on titanium dioxide (TiO2) from Nanopac. In the exhaust gas section A there were the first exhaust gas temperature and pressure sensors 11a and the first sensors for the concentration of particles and chemical pollutants 12a, and between the fabric filter 4 and the fan 3 there were second exhaust gas temperature and pressure sensors 11b and the second sensors for the concentration of particles and chemical pollutants 12b. The exhaust gas temperature and pressure sensors 11a and 11b were Pt1000 resistance sensors and steel probes, respectively, connected to a DE28 differential pressure transducer. The sensors for the concentration of particles and chemical pollutants 12a and 12b were the probes of the exhaust gas analyzer testo 380. The exhaust gas temperature and pressure sensors 11a and 11b as well as the particle and chemical concentration sensors 12a and 12b were connected to the control module in the form of the DP1S controller, which in turn was connected to fan 3. The power module 13 in the form of a battery and inverter from SMA Sunny Island was connected to a photovoltaic panel 14 attached to the device housing 2. The position of the photovoltaic panel 14 in relation to the sun was set by means of a mechanism controlling its position 15 consisting of two actuators. The voltage converter, which was a TELTO transformer, was connected to the power supply module 13. The voltage converter produced 24 V constant voltage, which supplied the DE28 differential pressure converter. The voltage converter also supplied 230 V, which powered the fan 3 and the control module.

Sequential purification and recovery of heat from the flue gas from the boiler room, where coal and other fuels were burned, was carried out using the device shown in the embodiment. The purification and heat recovery from the flue gas consisted in the fact that the flue gas emitted from the chimney 1 was directed through the flue gas discharge section A to the flue gas purifying section B, in which flue gas was cleaned on a cylindrical ceramic foam filter 9 with a sprayed absorption solution with a buffer substance. 80% of the exhaust gases were removed. with efficiency, aerosol particles containing polycyclic aromatic hydrocarbons and heavy metals as well as sulfur and nitrogen compounds. The used absorption solution with increased temperature due to contact with hot flue gas along with impurities collected from flue gas was collected in the liquid tank 6. From there it was directed to the heat exchanger 7 where heat was recovered from it. Subsequently, the cooled contaminated absorption solution was directed to the absorption solution regeneration device 8 and, after refilling, it was fed back to the absorption solution spray with the buffer substance 5. The pollutants remaining in the exhaust gas along with some of the spray absorption solution carried by the discharged exhaust gas were trapped on a fabric filter. When firing up the boiler, the control module set the fan 3 to optimal speed. This made it easier to ignite the boiler and prevented the boiler room from becoming cloudy. After firing up the boiler, the information about this fact was transmitted by the flue gas temperature and pressure sensors 11a and 11b to the control module, which from that moment adjusted the rotational speed of the fan 3 so that a stable negative pressure in the range of 10-25 Pa was required in the chimney duct. Increase in flue gas flow resistance due to the accumulation of pollutants on

The use of a cylinder-shaped foam ceramic filter 9 or a fabric filter 4 increased the pressure difference of the exhaust gas at the inlet and outlet of the device. Based on the signals from the exhaust gas temperature and pressure sensors 11a and 11b, the control module increased the fan speed 3, respectively. After exceeding the set maximum fan speed 3, the control module sent a signal informing about "clogging" of the cylinder-shaped ceramic foam filter 9 or the fabric filter 4. o and the need to replace them. The burnout of the boiler was reported by the flue gas temperature and pressure sensors 11a and 11b. The control module then turned off the fan 3 and stopped the circulation of the absorption solution. The cylinder-shaped foam ceramic filter 9 and the fabric filter 4 were regenerated after 10 days of intensive use and replaced after the end of the heating period.

List of designations

- chimney

- device case

- fan

- filter

- sprinkler of absorption solution with buffer substance

- liquid reservoir

- heat exchanger

- liquid regeneration device

- cylinder-shaped foam ceramic filter

- engine

11a, 11b - exhaust gas temperature and pressure sensor

12a, 12b - concentration sensor for aerosol particles and chemical pollutants

- power module

- photovoltaic panel

- position control mechanism

A - flue gas discharge section

B - exhaust gas cleaning section

Claims (5)

Patent claims A device for sequential cleaning and heat recovery from the exhaust gases emitted from the chimney, having a fan and exhaust gas cleaning filter, characterized in that in the device housing (2) mounted on the chimney (1) there is a fume discharge section (A) and a fume cleaning section ( B), while in the exhaust gas cleaning section (B) there is a fan (3) on the outlet side, a filter (4) and a sprinkler for the absorption solution with a buffer substance (5), under which there is a liquid tank (6), which is connected to with a heat exchanger (7), which in turn is connected through a liquid regeneration device (8) with a sprayer of the absorption solution with a buffer substance (5), and a cylinder-shaped ceramic foam filter (9) is partially immersed in the liquid reservoir (6), the upper part covers the inlet from the exhaust gas discharge section (A) to the exhaust gas cleaning section (B), the cylindrical foam ceramic filter (9) being connected at its perpendicular axis to the direction of exhaust gas flow with the engine drive shaft (10). 2. The device according to claim The method of claim 1, characterized in that the surfaces of the cylindrical ceramic foam filter (9) are coated with a catalytic substance. 3. The device according to claim The method of claim 1, characterized in that in the exhaust gas discharge section (A) there are first exhaust gas temperature and pressure sensors (11a) and first sensors for the concentration of aerosol particles and chemical pollutants (12a), and in the exhaust gas cleaning section (B) between the fan (3) and the filter (4) there are second exhaust gas temperature and pressure sensors (11b) and second sensors for the concentration of aerosol particles and chemical pollutants (12b), while the exhaust temperature and pressure sensors (11a, 11b) and the concentration sensors for aerosol particles and chemical pollutants ( 12a, 12b) are connected to the control module which is connected to the fan (3). 4. The device according to claim A device according to claim 2, characterized in that the fan (3) and the control module are connected to a voltage converter which is connected to the power module (13). PL 232 868 Β1 5. The device according to claim 1 3. The device according to claim 3, characterized in that the power module (13) is connected to a photovoltaic panel (14) which is fixed to the chimney (1) or to the housing of the device (2) through a mechanism controlling its position (15).