SE0901351A1 - Technical solution of combined return air in combination with ionization - Google Patents

Abstract

The invention relates to a ventilation system, comprising a supply air duct (1) for. Conduction of a flow of supply air to at least one space (5,6), an exhaust air duct (2). for directing exhaust air from at least one space (5, 6) and a return air duct (9) for directing at least a part of the exhaust air flow to the supply air duct (1). The invention is characterized in that the system contains an oxidation-enhancing device (12). In one of the ducts (1, 2,9) and an air quality meter that controls the oxidation-enhancing device.

Description

and exhaust air increases. A disadvantage of this is that the energy value in the heated, or cooled, indoor air disappears.

The possibilities for limiting energy losses, associated with emitted indoor air, are not unlimited, as ventilation of spaces is regulated in various ways by limit values, recommendations and requirements from authorities with regard to e.g. air quality class and air turnover.

In order to recover energy in the indoor air, it is known to return a proportion of the exhaust air to the flow of supply air so that a return flow with recirculating air is obtained. This works well from an energy point of view, but as the inflow of fresh outdoor air typically decreases in step with increasing return air flow, larger return air flows can have problems with the air turnover becoming too low. This can result in the levels of e.g. C02 and malodorous substances become high.

To avoid such problems, the National Board of Housing, Building and Planning recommends a maximum of 40% return air.

Another known way of recovering energy in indoor air is to heat-exchange exhaust air with supply air. Usually either rotary heat exchangers or plate heat exchangers are used for this purpose. The former have a relatively high efficiency but can due to its moving parts have problems with wear and deterioration. Plate heat exchangers generally have no major functional problems, but on the other hand have a lower efficiency. General problems that can arise with conventional heat exchangers are odor leakage, and that they become dirty and thus have a lower efficiency.

There is thus a need to improve the possibilities for recovering energy in indoor air.

DISCLOSURE OF THE INVENTION The object of this invention is to provide a ventilation system which enables increased energy savings in a better way than known systems. This object is achieved with a system and a method according to claims 1 and 13. The dependent claims constitute advantageous embodiments, developments and variants of the invention. The invention relates to a ventilation system, comprising supply air duct for directing flow of supply air to at least one space, exhaust air duct for directing flow of exhaust air from the at least one space, and return air duct arranged to allow at least a part of the exhaust air flow to be led into supply air duct. The ventilation system according to the invention further comprises some form of oxidation-accelerating device, such as a UV lamp, air ionizer, electrical barrier discharge, ozone generator or the like are arranged so that oxidation is accelerated in one of the channels.

By increasing the air's ability to oxidize, growth of microorganisms is prevented, bacteria are killed and the presence of odorants is quickly reduced, which allows more return air to be used with accompanying energy savings when less energy-bearing, hot or cooled air needs to be returned.

Due to the increased proportion of return air, a lower air turnover is also allowed, ie the amount of air that is transported in and out of the building. Smaller fans and ducts as well as filters and smaller possible heat exchangers need to be installed. Lower investment costs and lower operating costs will result.

The need for heat exchangers between exhaust air and outdoor air is reduced. This is an advantage as heat exchangers are expensive, have a limited efficiency and are associated with problems such as loss of function, wear and tear and odor leakage. Furthermore, heat exchangers provide an increased pressure drop that requires higher fan power for the same air circulation.

Oxidation enhancing devices, such as UV lamps, air ionizers, electric barrier discharge and ozone generators are used to break down gases, kill bacteria and sterilize the air in many industrial processes and also in healthcare. The air becomes more oxidative and reactive.

The invention allows an increase in the return air flow from the current (in Sweden) recommendation of 40%. This means that very large energy savings are achieved, at the same time or, if particularly desired, the air of the premises can be purified, sterilized and made less risky during epidemics or as desired through increased circulation.

Pure dilution of, for example, viruses spread from a sneeze in the room is diluted simplified so that a halving takes place in step with the number of air changes - ie 50% dilution in one air exchange and 50% of 50% in two air changes, etc. - ie logartimically. If the recycled part is completely cleaned, it corresponds to an air exchange and dilution in the same way. It is not possible to achieve 100% purification, nor optimally economically. An increased recirculation of the air with say 90% degree of purification quickly provides better air quality, in terms of the spread of infection in the room, compared to increasing the purity with only increased air exchange through the supply of new outdoor air. Even an extra recirculation of indoor air then corresponds to 90% of supplying the same amount of outdoor air - seen as pure dilution.

Bacteria, viruses, pollen, allergens and other particles can be easily reduced by over 90% for each indoor air recirculation. Gases are oxidized to varying degrees with perhaps 75% for each circulation. It is also possible to regenerate carbon dioxide, but not economically defensible, and therefore the CO2 content can often be used as an indicator of when an increased amount of outdoor air is to be supplied for dilution.

The principle of increasing the oxidation rate can be applied in any of the supply air, exhaust air and return air ducts. In an advantageous embodiment of the invention, however, the oxidation accelerating apparatus is placed in connection with the supply air duct in such a way that the more oxidative air is supplied to the supply air duct. Thereby, the more reactive air is added only to the air flow which passes on to the spaces to be ventilated. Conveniently, the oxidation raising apparatus is arranged so that the oxidative air is supplied to the supply air duct in a position downstream of the return air duct. In this way it is avoided that a significant proportion of oxidative air, which is reactive, has time to be consumed before it comes into contact with the return air flow, i.e. the proportion of the exhaust air flow that is recirculated in the system.

The invention also relates to a method for operating a ventilation system of the type described above.

DESCRIPTION OF THE FIGURES The invention will now be described in more detail with reference to figures in which: Figure 1 shows in a schematic view, a preferred embodiment of the invention.

PREFERRED EMBODIMENTS Figure 1 shows, in a schematic view, a preferred embodiment of a ventilation system according to the invention. Outdoor air is sucked into a supply air chamber 1 ', which forms part of a supply air duct 1, via an outdoor air damper 16 by means of a supply air fan 3. The supply air duct 1 leads further and branches off to a first and second space 5, 6, to which spaces a flow of supply air is carried via supply air outlet 21 when the supply air fan 3 is in operation. From the first and second space 5, 6, respectively, exhaust air inlet 22 leads via an exhaust air duct 2 to an exhaust air chamber 2 ', which forms part of the exhaust air duct 2. An exhaust air fan 4 placed in the exhaust air chamber 2' sucks a flow of exhaust air from the spaces 5, 6 via the exhaust air duct 2 to the exhaust air chamber 2 '.

A flow connection constituting a return air duct between the exhaust air chamber 2 * and the supply air chamber 1 'is arranged through a return air damper 9 located between the two chambers. An exhaust damper 18 is arranged at the outflow from the exhaust air chamber 2 '. When the flow of exhaust air via the exhaust air ducts 2 reaches the exhaust air chamber 2 ', a part of the exhaust air flow will go out via the exhaust air damper 18 and leave the system via exhaust air hood 17 while the remaining part of the exhaust air flow will be led into the supply air chamber 1' via the return air damper 9. . How large a part of the total exhaust air flow that forms return air flow depends, among other things, on on the return air damper 9 and the exhaust air damper 18, respectively, size and opening area. For example, the return air damper 9 and the exhaust air damper 18 can be arranged and regulated in such a way that 80% of the exhaust air is recirculated as return air.

In connection with the supply air duct 1, one or more, air quality meters 11 are arranged, which can register levels of CO 2, air ions, particles or what is considered suitable, in addition to oxidation-enhancing device 12, and meters for checking air quality 13.

Air quality meter 11 is arranged to register the air quality you wish to measure, for example CO 2 in the supply air, in order to increase the intake of outdoor air unless the registered content is lower than a certain limit value which depends on the application. To increase the intake of outdoor air, the effect on the supply air fan 3 can be increased and / or the opening area of the outdoor damper 16 can be increased. Correspondingly, the power of the fan can be reduced when the limit value, for example 300 ppm, is below. This reduces electricity consumption and also reduces any fan noise.

It is the oxidation-enhancing devices 12 which have the function of increasing the decomposition of substances interfering with the air, and thereby creating good air quality in the air which in this example constitutes 80% of return air. The oxidation enhancing device (s) 12 can in principle be placed anywhere in the supply air duct 1, where of course the duct can constitute one or more ducts. If the supply air duct 1 branches into several spaces, as for example in figure 1, oxidation-enhancing device 12 is suitably placed upstream of the branch or branches in order to be able to contact the entire flow of supply air with increased oxidation.

Alternatively or as a complement, several oxidation enhancing devices 12 may be used downstream of each other or downstream of the branch or branches.

Which oxidation or effect is necessary depends mainly on the total air flow and the amount of pollutants in the air to be purified. It is a dimensioning issue. A constant effect from oxidation enhancing device may be appropriate when contaminants and air flow can be considered to be relatively constant. In systems with varying air fl fate, the oxidation increase can suitably also be varied with the air flow. By equipping the system with air quality meters, the need for oxidation increase can be controlled based on real-time measurement results or from historical measurement results or from expected future conditions, such as meteorological data.

A first air quality meter 13 checks air quality downstream, typically a few meters downstream of oxidation enhancing device 12, in order to alert if measured quality factor, for example, would exceed a limit value, which may be given by authorities or determined by users.

When a limit value at any air quality meter 13-15 is exceeded, it is suitably arranged so that one or more of the following measures are taken: an error signal is given, the oxidation-raising device is regulated, the power of the supply air fan 3 is affected and / or the return air damper is regulated.

The ventilation system further comprises a control unit (not shown) to which all air quality meters, sensors, oxidation-enhancing devices, dampers and fans are connected. The control unit receives values from all units and is arranged to be able to control fans and oxidation-raising devices based on received data and set limit values, etc. One or more adjustable dampers can also be connected to the Control Unit to enable control and monitoring of these as well.

Ducts and chambers can contain, for example, means for filtration as well as temperature and humidity control of the air.

A damper normally comprises a movable part which can be set in different positions to regulate an opening area in a flow channel through the damper.

The invention is not limited to the embodiment described above but can be varied within what is defined by the appended claims.

For example, the return air duct, or ducts, may be constituted by something other than an opening in a damper; the return air duct can e.g. consists of only one opening without any adjustable damper or of a longer duct which may be provided with different types of dampers and valves.

Furthermore, air quality meters 11, for example CO 2 sensors, can be placed in alternative positions as long as its function is useful.

Claims (7)

PATE NTK RAV Ventilation system for premises, comprising - at least one supply air duct (1) for directing the flow of supply air to at least one space (5, 6), - at least one exhaust air duct for directing the flow of exhaust air from at least one space (5, 6) out out of the system, and - at least one return air duct (9) for directing at least a part of the exhaust air flow to the supply air duct (1). characterized in that the system comprises oxidation enhancing device (12) arranged to increase the oxidation in one of the channels (1, 2, 9). Ventilation system according to claim 1, characterized in that the oxidation-raising device (12) is located adjacent to the supply air duct (1) in such a way that oxidation in the air increases in the supply air duct (1) through the oxidation-raising device (12). Ventilation system according to claim 2, characterized in that oxidation-increasing device (12) is arranged so that oxidation increases in supply air knob (1) in a position downstream of return air duct (9). Ventilation system according to Claim 1 or 2, characterized in that the air quality meter (13) is located in the exhaust air duct (2). Ventilation system according to Claim 3 or 4, characterized in that the air quality meter (13) is located downstream of the oxidation-increasing device (12). Ventilation system according to one of the preceding claims, characterized in that the system comprises a CO 2 meter (11). Ventilation system according to claim 6, characterized in that the system comprises a CO 2 meter (11) located in the exhaust air duct (2). Ventilation system according to one of the preceding claims, characterized in that an air quality meter (14) is located in at least one space (5). Ventilation system according to one of the preceding claims, characterized in that the supply air fan (3) is arranged in connection with supply air duct (1) Ventilation system according to claim 9, characterized in that oxidation-increasing device (12) is located downstream of the supply air fan (3). Ventilation system according to one of the preceding claims, characterized in that the exhaust air fan (4) is arranged in connection with the exhaust air duct (2). Ventilation system according to one of the preceding claims, characterized in that it comprises a control unit for controlling and controlling components included in the system. Method for operating a Ventilation system for premises comprising - supply air duct (1) for directing a flow of supply air to at least one space (5, 6), - exhaust air duct (2) for directing flow of exhaust air from at least one outlet (5, 6) ) out of the system and, - return air duct (9) arranged to allow at least a part of the exhaust air flow to be led into the supply air duct (1), - characterized by - that oxidation-increasing device affects the air in one of the ducts (1, 2, 9. Method method according to claim 13, characterized in that the oxidation-increasing device affects the air in the supply air flow Method according to claim 13 or 14, characterized in that a content of CO2 in the system is registered and that the flow of supply air is regulated depending on the registered content of CO2.