RU2202372C2 - Apparatus for air regeneration in room - Google Patents

Abstract

FIELD: equipment for degassing, deodorizing and disinfecting of air medium in premises. SUBSTANCE: apparatus has casing incorporating dust-catching air filter and air fan, as well as gaseous ozone generator and preliminary oxidation chamber. Mixing members mounted in preliminary oxidation chamber are made in the form of continuous or netted strips connected with their ends so as to define geometric body with single-side surface in space. Mixing members are made of material inert with respect to ozone. Apparatus is further equipped with cartridge and solid dispersed sorbent. One part of solid dispersed sorbent layer is covered with solid non-volatile oxidizer and other part is covered with solid non-volatile gaseous ozone decomposition product. Apparatus allows complete deodorizing and degassing of medium in room, removal of microorganisms and viruses from air to be effected, and may operate in the presence of living creatures. EFFECT: reduced consumption of ventilation air and power consumption for heating thereof. 1 dwg, 1 ex

Description

 The invention relates to devices for degassing, deodorizing and disinfecting the air in rooms: industrial, public, residential buildings and premises, to maintain the composition of the air at the required sanitary level.

 Widely known installations for the regeneration (degassing, deodorization) of air in rooms in which solid dispersed sorbent is used as an absorber of harmful and smelling substances - activated carbons of various grades, aluminum oxide, silica gel and others. The cleaned air passes under the pressure created by the fan through a layer of dispersed sorbent. In this case, the substances contained in the cleaned air are adsorbed on the surface of the sorbent, and the cleaned air enters the same room (1).

 A disadvantage of the known is that the air purification process proceeds to the full use of the adsorption capacity of the sorbent. But this adsorption capacity is small and amounts to about 1: 1000 units of the weight of adsorbed substances to the weight of the sorbent when the adsorbed substances are completely filled with the active surface of the sorbent, which necessitates frequent replacement of an expensive sorbent.

 The process of adsorption of many substances on the surface of the sorbent is irreversible, as a result of which the regeneration of the adsorption properties of the sorbent is a complex technological process that is unprofitable to carry out at the place of use of the sorbent if about several tons of sorbitol are not used in the air purification process at the same time.

 It should be noted that with constant air recirculation through the sorbent, the latter accumulates microorganisms contained in the purified air, which, remaining on the surface of the sorbent, retain their biological activity: their development can lead to the fact that the sorbent will become a source of bacteriological air pollution even before loss them their adsorption properties due to the accumulation of harmful substances on the surface of the sorbent. In addition, the assessment of the loss of the cleaning ability of the sorbent is usually carried out using weekly experiments, and most often by periodic sampling of air and their analysis, which requires the reliability of the installation to conduct a large number of expensive, time-consuming and time-consuming analyzes of indoor air samples.

 The above disadvantages do not allow the widespread use of air purification plants in rooms where the solid dispersed sorbent serves as the cleaned air agent.

 The closest in technical essence to the proposed solution and taken as a prototype is an apparatus for the forced distribution of air, containing a housing, a dust filter and a fan (2).

 A disadvantage of the known solution is that in the known device, the air is cleaned only of dust, gaseous, vaporous, toxic and foul-smelling substances that can be released into the atmosphere of the room during technological processes and adversely affect the health of people in these rooms by such an apparatus not removed from the air. This does not ensure the degassing and deodorization of the air environment of the room. In addition, the dust filter located in the device’s case does not remove microorganisms and viruses from the air, i.e. does not provide air disinfection.

 As a result of this, the prototype does not provide a reduction in the flow of ventilation air necessary to maintain the proper sanitary and hygienic condition of the indoor air environment, and the heat consumption for heating the ventilation air in winter remains high.

 The present invention is aimed at eliminating the above disadvantages and the following technical result can be obtained from use: reducing the consumption of ventilation air, energy consumption for heating it in the cold season, while maintaining the sanitary and hygienic standards of the air environment of various premises, the ability to function in the presence of living things.

 This is achieved by the fact that an air regeneration installation is placed in the treated room, which consumes electrical energy for operation and consists of a housing with a dusty air filter placed in it, a pressure air fan, a gaseous ozone generator, and a preliminary oxidation chamber containing static mixing elements in the form of solid or mesh tapes connected at their ends, having rigidity sufficient to withstand airflow without losing the desired shape, nnye inert towards ozone gas material; solid dispersed sorbent placed in an airtight cartridge.

Moreover, the static mixing elements are connected by their ends so that they form a geometric body with a one-sided surface, that is, a Moebius band; a solid dispersed sorbent located in the cartridge consists of at least two parts in a volume ratio of 1: 9 to 9: 1; on the surface of that part of the solid dispersed sorbent layer, which faces the inside of the unit, a solid non-volatile oxidizing agent is applied, which is the highest metal oxides of groups V, VI and VII of the Periodic Table, for example, V ₂ O ₅ , MnO ₂ , Mn ₂ O ₇ , in an amount no more than 10% by weight of the sorbent; on the surface of the part of the solid dispersed sorbent layer, which faces the air of the room, a solid non-volatile catalyst for the decomposition of gaseous ozone to molecular oxygen is applied, which is an oxide of metals of group VIII of the Periodic Table, for example CaO, NiO, in an amount of not more than 5% by weight of the sorbent.

 The drawing shows an installation for the regeneration of indoor air, a General view.

The positions in the drawing indicate:
1 - installation casing;
2 - air dust filter;
3 - pressure air fan;
4 - generator of gaseous ozone;
5 - chamber pre-oxidation;
6 - static mixing elements;
7 - solid dispersed sorbent;
8 - cartridge;
9 - a layer of sorbent with a solid non-volatile oxidizing agent;
10 - sorbent layer with a solid non-volatile catalyst.

 The device for air regeneration in the room consists of a housing 1, in which a dust filter 2, a pressure air fan 3, an ozone gas generator 4, a pre-oxidation chamber 5 containing static mixing elements 6, made of a material inert with respect to gaseous ozone, and designed for transverse mixing of the ozone-air flow without significant loss of pressure created by the fan 3. The volume occupied by the mixing elements 6 is not olee 0.01 preoxidation of the volume chamber. These elements are solid or mesh tapes with a stiffness sufficient to withstand the air flow without losing their original shape, while the ends of each of the tapes are connected so that they form a geometric body in space with a one-sided surface, that is, a Moebius tape. The number of mixing elements 6 in the preliminary oxidation chamber 5 is not less than one. They are located in planes close to perpendicular to the direction of movement of the air flow and are statically fixed. A solid dispersed sorbent 7 is installed in an airtight cartridge 8, blocking the air flow leaving the pre-oxidation chamber. The layer of solid dispersed sorbent 7 in the cartridge 8 is divided into at least two parts 9 and 10, in a volume ratio of 1: 9 to 9: 1. On the surface of the part of the layer of solid sorbent 9, facing the gas stream exiting the pre-oxidation chamber 5, a solid non-volatile oxidizing agent is applied, which is the higher metal oxides of groups V, VI, and VII of the Periodic Table in an amount of 0.01 to 10% by weight of the sorbent; on the surface of part 10 of the sorbent layer facing the air of the room, a solid non-volatile catalyst for the decomposition of gaseous ozone to molecular oxygen is applied, which is a metal oxide of Group VIII of the Periodic Table, in an amount of not more than 5% by weight of the sorbent.

 Installation for air regeneration in the room works as follows.

 The installation is placed in a room where continuous degassing, deodorization and disinfection of the air in the presence of living beings is required. The cleaned air passes sequentially through the nodes of the device in the following order: first, the air is cleaned of dust on the dust filter 2 and through a pressure fan 3 is blown through a gaseous ozone generator 4, where ozone is generated from the oxygen of the cleaned air under the influence of an electric discharge in an amount of not more than 5 and not less than 1 volume percent of the volume of purified air passing through the ozone generator. After that, the ozone-air mixture enters the pre-oxidation chamber 5, where it is transversely mixed when moving through the chamber 5 with the mixing elements 6 without losing more than 5% of the pressure of the gas stream leaving the ozone generator. In the preliminary oxidation chamber 5, complete and partial oxidation of harmful and odorous substances occurs during their interaction with ozone and the death of microorganisms under the influence of ozone.

 The cross-mixing of the gas stream created by the mixing static elements 6, made in the form of Moebius tapes, significantly intensifies the interaction processes between gaseous ozone and harmful, smelling substances and microorganisms in the cleaned air without the need to fill the volume of the pre-oxidation chamber with 5 different nozzle elements providing the same mixing the gas stream, but reducing the working volume of the chamber and creating significant pressure losses air, which reduces the productivity of the installation in purified air at the same pressure created by the air fan 3. After passing through the pre-oxidation chamber 5, the air stream containing excess gaseous ozone, products of incomplete oxidation of harmful substances by ozone, the decomposition of microorganisms under the action of ozone, passes through solid dispersed sorbent is an inner layer on the surface of which a solid non-volatile oxidizing agent is applied. The products of incomplete oxidation of substances, the decomposition of microorganisms are adsorbed on the surface of a solid dispersed sorbent and are oxidized both by gaseous ozone and in the process of surface oxidation by a solid oxidizer located on the surface of the sorbent. In this case, complete and faster oxidation and destruction of substances adsorbed on the surface of the solid sorbent occurs under the action of two oxidizing agents in different states of aggregation. The substances adsorbed on the surface of the sorbent, decaying under the influence of these oxidizing agents, release the surface of the sorbent, thereby restoring its adsorption properties.

 The solid oxidizer, having lost during the oxidation of products of incomplete ozone oxidation of harmful substances adsorbed from the cleaned air, interacts with the residual gaseous ozone, turning back into the oxidized form, capable of reacting again with the next portions of the products of incomplete ozone oxidation of harmful substances adsorbed from continuously supplied air and decomposition of microorganisms under the action of ozone in the pre-oxidation chamber 5.

 Thus, the adsorption properties of the solid sorbent are regenerated, the oxidative properties of the solid non-volatile oxidizing agent are restored under the influence of residual ozone, which significantly increases the life of the sorbent and the solid, non-volatile oxidizing agent deposited on its surface.

 Further, the stream of purified air containing residual ozone passes through a part of the sorbent layer facing the external environment of the room, with a solid, non-volatile catalyst for the decomposition of ozone to molecular oxygen deposited on this part. During the movement of air purified from harmful, odorous substances and microorganisms, but containing gaseous residual ozone, the residual ozone interacts with the catalyst located on the surface of the sorbent, while the residual ozone decomposes to molecular oxygen.

 Thus, the air, after passing through degassing, deodorization and disinfection, is fed into the air of the room with the ozone content in it at concentrations close to the MPC, which allows living things to be in the room during continuous operation of the installation in this room.

 The use of such a installation allows to reduce the consumption of ventilation air, previously required to maintain the sanitary-hygienic characteristics of the air environment, and significantly reduce energy consumption for heating ventilation air in the cold season.

 EXAMPLE.

 An implementation example applies to a specific object.

 Object - a classroom of a comprehensive school with a long stay of students in the amount of 20 people, under 12 years old, Krasnoyarsk.

1. The volume of the room: 169 m ³ .

2. Room temperature: +16 ^o C. The temperature (average) of the environment during the heating period -7.2 ^o C.

 3. The duration of the heating period: 235 days.

4. Air pollution type room environment: _CO2 recovery, harmful and odorous waste products people microorganisms.

5. Consumption of ventilation air per person to maintain the sanitary-hygienic state of the air of the classroom: 25 nm ² / h.

 6. Duration of ventilation: at least 8 hours a day.

 7. Thermal power required to heat the ventilation air during the heating period: 277 kcal / h (3.222 / kW).

 8. The cost of thermal energy for heating the ventilation air during the heating period: 5.21 Gcal (6057.36 kW / h).

When placing an air regeneration unit in the classroom room in this room, the air flow is necessary only for the assimilation of human emissions of carbon dioxide and is 7nm ³ / h per person.

9. Air consumption for ventilation when using the installation for air regeneration: 140 nm ³ / hour = 7 nm ³ / hour. • 20 people

 10. Thermal (average) power spent on heating ventilation air: 776 kcal / h (0.902 kW).

 11. Total heat consumption for heating the ventilation air during the heating period: 8.46 Gcal (1696 kW).

12. Electric power (total) consumed by the air purification installation of a room for this purpose: 1.6 W / m ³ (0.3 kW). With a total installation capacity of purified air 60 nm ³ / hour.

 13. Power supply: ≈220 V.

 14. Installation weight: 4.5 kg.

 15. Overall dimensions: 115 • 160 • 370 mm.

 Total energy costs for the heating period for the operation of the air recovery unit: 564 kW • hour; taking into account the costs of heating the ventilation air: 1696 + 564 = 2260 kW • h, which is 37.3% of the energy consumed for heating the ventilation air without operating the unit.

 Typically, in a room of this type (a large number of people stay for a long time without performing production processes) about 60% of the total heating load of the building is accounted for by heating the ventilation air and reducing the heat energy consumption for heating the ventilation air by 62.7% when using the unit reduces heating costs in the cold season by 37.6%.

Additional effect: with continuous disinfection of the air of a room with a long stay of a large number of people in this room (from 3.5 m ³ to 17 m ^{3 of the} volume of the room per person), the health status of these people is significantly improved, since the spread of infectious diseases is prevented in the room diseases transmitted by airborne droplets and airborne dust.

Control measurements of air samples taken from the preliminary oxidation chamber showed that the concentration of ozone in it is about 0.15-0.1 g / nm ^{3 of} air.

This concentration of ozone provides almost instant and complete death of microorganisms. Measurements of the ozone concentration in the purified air leaving the unit showed that the ozone content in it does not exceed 0.01-0.02 mg / nm ^{3 of} air (MPC for ozone 0.1 mg / nm ³ , the odor sensitivity threshold is 0.016 mg / nm ³ ).

Measurement of ozone concentration in the air, carried out during the operation of the installation showed that the stationary concentration of ozone in the volume of the room does not exceed 0.01 mg / nm ^{3 of} air and in many cases is below the analytical limit. The concentration of ozone in the air of the preliminary oxidation chamber in the air leaving the unit was determined using an AF-2 ozonometer and duplicated according to the method of GOST 18301-72 "Methods for the determination of residual ozone". In addition, the installation for air regeneration of premises for various purposes can be operated in the absence of living creatures in the mode of operation of a conventional ozone gas generator, for which a cartridge containing a solid dispersed sorbent is made removable.

When the unit is operating in the ozonation mode of the entire volume of the room and the surfaces of the equipment and objects located in it, the cartridge, in whole or in part, is removed from the path of the air stream leaving the preliminary oxidation chamber, and the ozone-air mixture with a high content (about 0.1 g / nm ³ ) ozone enters the room volume. The duration of this mode is set automatically for a given time. After processing the room in the ozonation mode, the latter is forcibly ventilated or the time required for spontaneous decomposition of ozone to molecular oxygen is maintained (until the safety of ozone concentration is achieved).

 In this case, as mentioned above, there is a degassing, deodorization and disinfection of the surfaces of objects located in the volume of the treated room at the same time as cleaning the air environment of the latter under the action of gaseous ozone emitted by the generator.

Sources of information
1. Birkalov B.V., Karpis E.E. Air conditioning in industrial, public and residential buildings. M .: Publishing. construction literature, 1971, p. 179.

 2. RF patent 2090495, С 01 В 13/11, 09/20/1997, prototype.

Claims (1)

 A room air regeneration installation comprising a housing and a dust filter and a pressure air fan located therein, characterized in that it further comprises an ozone gas generator, a pre-oxidation chamber in which static mixing elements are installed in the form of continuous or mesh belts, which are connected at their ends in such a way that they form a geometric body in space with a one-sided surface, that is, a Mobius strip, and have rigidity, sufficient to withstand airflow without loss of a given, while they are made of inert material with respect to gaseous ozone, a cartridge, a solid dispersed sorbent located in the cartridge, consists of at least two parts in a volume ratio of 1: 9 to 9: 1, moreover, on the surface of that part of the solid dispersed sorbent layer that faces the inside of the installation casing, a solid non-volatile oxidizing agent is applied, which is the highest metal oxides of groups V, VI, VII of the Periodic Table, in an amount of not more than 10% of m ssy sorbent, and on the surface of the layer of solid particulate sorbent, which faces the room air environment, applied involatile solid catalyst decay of ozone gas, which is a Group VIII metal oxides of the Periodic Table, in an amount of not more than 5% by weight of the sorbent.