FI82547C - FOERFARANDE VID MASKINELL LUFTKONDITIONERING OCH ETT FOER GENOMFOERANDE AV FOERFARANDET AVSETT VENTILATIONSSYSTEM. - Google Patents

Description

82547

Method in mechanical ventilation and ventilation system for the implementation of methods Förfarande vid maskinell luftonditionition och et för genomförande av förfarandet avsett ventilationssystem 5

The invention relates to a method in mechanical ventilation, in which a room of a building or the like is ventilated by a control network with automatic control, and in which room air with thermal energy and in which method the supply air blown into the room 15 is further heated by a liquid circulating heating circuit after said heat recovery cell before being blown into the room.

The invention also relates to a ventilation system comprising an air-20 exchange device adapted to suck exhaust air from a room heated by a separate heating network with automatic control and to blow outdoor air into said room space, the ventilation device being provided with a heat recovery cell arranged to be heated and with heat-25 energy supply air from the outside before it is blown into the room, by means of a heat exchanger and whose heating circuit formed by the auxiliary heating cell and the heat exchanger is liquid-circulating.

Various ventilation devices and ventilation control devices 35 which are adaptable to the room space and which have ventilation ducts for fresh air entering the room and exhaust air leaving the room are already known. Known device solutions also show the use of different fans and filters, so that said 2 82547 components are arranged integrated in the ventilation device itself. However, these previously known equipment solutions and methods have a number of different disadvantages, in particular with regard to the introduction of fresh air into the room and the complexity of the equipment.

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Since the energy of the exhaust air removed from the room is not always sufficient to heat the outdoor replacement air sufficiently in cold weather, this replacement air must be heated further after the heat recovery cell of the ventilation unit so that the fresh air supplied to the room does not cause indoor draft. Previously, the reheating of the replacement air taken from the outside has been treated e.g. so that the ventilation device is provided with an electric resistor or other electrically operated heating cell after the heat recovery cell, with which the fresh air is heated before blowing into the room. However, electric post-heating devices 15 have several different disadvantages. According to one embodiment, such an electrically operated post-heating device is already set at the factory to a fixed control value. However, this is a bad solution because the heating demand of the blown air is not always the same, but varies according to the outdoor temperature. Thus, a fixed post-20 heating device does not always provide air at a suitable temperature in the room. According to a more advanced embodiment, such an electric reheating device is provided with a separate controller or control circuit with which the power of the reheating device can be adjusted. Such an arrangement provides air of a suitable temperature for the room, but the disadvantage of such an arrangement is that the reheating device requires its own controller or control circuit, which makes the system complex, expensive and quite susceptible to interference.

It is an object of the present invention to provide a method and a ventilation system which avoid the disadvantages described above and which provide a significant improvement over the previously known solutions. To achieve this, the method according to the invention is mainly characterized in that the temperature control of the liquid circulating heating circuit is performed by the control automation of a building or a similar heating network in such a way that the

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The temperature of the intake air taken in 3 82547 changes in a way that corresponds to the temperature of the heating network.

The ventilation system according to the invention, in turn, is characterized in that the temperature of the heating circuit is adapted to be controlled by the automatic control of the ldm measuring network so that the temperature of the supply air to the room.

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Thus, in the solution according to the invention, the post-heating of the air blown into the room is treated by a liquid circulating post-heating device, the control system of which is connected to the actual heating network control system of the building. The solution according to the invention therefore does not require its own and separate control system for post-heating. As a result, the invention has the significant advantage that there is less source of interference in the control of the heating of a building than in conventional systems, whereby the system according to the invention is substantially more reliable than before. Other advantages and features of the invention will become apparent from the following detailed description of the invention, to which, however, the invention is not intended to be exclusively limited.

The invention will now be described in detail with reference to the figure of the accompanying drawing, which schematically shows a ventilation system according to the invention.

The ventilation system according to the figure is intended for dwellings, e.g.

30 for small properties and the like, which are equipped with a room heating system 30-35 and a ventilation system 10-19a separate from the heating system. The ventilation device belonging to the ventilation system is generally indicated in the figure by the reference number 10. The ventilation device 10 comprises fans 11 and 12, of which the first fan 11 sucks fresh replacement air from outside along the first air duct 15 and blows it through the second air duct 18 The second fan 12, in turn, sucks out of the room space along the third Air Duct 17 and blows it along the fourth Air Duct 19 into the outside air via the end piece 19a. A heat recovery cell 13 is arranged in the ventilation device 10, through which the air to be removed from the room 5 is made to pass before it is blown into the outside air. The heat recovery cell takes and stores heat from the air to be removed from the room so that the air blown out through the fourth air duct 19 is considerably colder than the air to be blown out of the room along the third air duct 17. Also, the external replacement air taken along the first air duct 15 10 is arranged to pass through said heat recovery cell 13, said heat recovery cell 13 heating the external replacement air before it is blown into the room through the second air duct 18. In addition, filters 14 and 16 are arranged in connection with the heat recovery cell 13 for filtering the air circulating through the ventilation device 15. In the arrangement according to the figure, the first filter 14 which filters the replacement air to be taken from the outside is a double filter in order to obtain the supply air to be blown into the room as clean as possible. The second filter 16 is arranged to filter the exhaust air to be removed from the room so that the impurities 20 are also not blown into the outside air.

As already stated above, the external replacement air is heated in the ventilation device 10 by a heat recovery cell 13 before the air is blown into the room. However, since in winter, when the outside air is cold, the energy of the exhaust air is not always able to heat the outside air sufficiently, the outdoor replacement air must be heated after the heat recovery cell 13 so that the supply air to the room does not cause draft to the occupants. As a result, a post-heating cell 1 is installed in the ventilation device 10 after the heat recovery supply cell 13, through which the supply air to the room has to pass before being blown into the room. According to the figure, the post-heating cell 1 is arranged downstream of the heat recovery cell 13 before the first fan 11, so that said post-heating cell 1 heats only the replacement air taken from the outside 35. The reheating cell 1 is liquid circulating, i.e. heated by liquid, and for this purpose the reheating cell 1 is connected

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5 to 82547 to a heat exchanger 2, from which a circulation pump 5 pumps a heated liquid along a supply line 3 to a post-heating cell 1, from which a cooled liquid circulates back to a heat exchanger 2 along a return line 4. In the liquid circulation circuit of the post-heating cell 1, a heat transfer medium having a very low freezing point 5 circulates to prevent freezing of said heat transfer medium. As said medium, for example, a mixture of water and glycol, industrial alcohol or the like can be used. Since a liquid circulates in the after-heating liquid circuit, which cannot freeze even at low temperatures, the expansion space of the circuit can be arranged simply 10, e.g. with a tube-expanding device 6 according to the figure 6. The expansion device 6 can thus breathe directly into .

The heat exchanger 2 of the liquid circulating column of the post-heating cell is connected directly to the heating network 30-35 of the building so that the post-heating cell does not need a separate control system for post-heating of the ventilation, but the post-heating is handled by said heating network control automation. Said heating network conventionally comprises a heating network heating and supply device 30 which heats 20 and supplies the heat transfer medium circulating in the heating network via the supply line 31 to the heating network, from where it returns via return line 32 to said heating and supply device. and a control device 34 which, via a three-way valve 33, controls the circulation of the heat transfer medium 25 in the heating network. For temperature control, a temperature sensor 35, which is mounted on a wall 36 or the like in a building, is connected to the regulation and control device 34. Said temperature sensor 35 measures the outdoor temperature and supplies control signals corresponding to said temperature to a control and control device 34 which, according to said signals 30, controls the circulation of the heat transfer medium in the heating network by means of a three-way valve 33.

According to the figure, the heat exchanger 2 is mounted on the supply line 31 of the heating network. Thus, the temperature of the heat transfer medium circulating in the liquid circulation circuit 35 of the post-heating cell 1 changes in a manner similar to the temperature of the heating network. Thus, the heating network control unit 6 82547 and the control device 34 control the temperature of the air blown into the room at the same time as the heating network temperature is adjusted. Thus, a separate heat control system is not required for reheating the air blown into the room. Since the heat exchanger 2 is connected to the supply line 31 of the heating network 5 with a high flow, said heat exchanger 2 did not significantly reduce the temperature of the heat transfer medium circulating in the heating network. The power of the heat exchanger 2 is, for example, of the order of 0.7 kW, which is small compared to the power absorbed by the radiators (heat exchangers) in the heating network.

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It is also essential for the uniformity of the temperature of the air blown into the room through the second air duct 18 that the post-heating cell 1 is arranged on the suction side of the first fan 11. On the pressure side of said fan 11, the air heated by the post-heating cell 1 is thus evenly distributed, whereby the air blown into the room is uniform and does not cause a feeling of draft.

The invention has been described above by way of example with reference to the figure of the accompanying drawing. However, it is not intended to limit the invention 20 to the example shown in the figure alone, but many modifications are possible within the scope of the inventive idea defined by the appended claims.

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Claims (8)

1. A method of mechanical ventilation, in which a room space is heated by a building or equivalent with a heating end (30-35) zone provided with control automation and in which the air in the room space is continuously exchanged by sucking air from the room space. the space with a ventilation device (10) belonging to the ventilation system and by conducting the air which is sucked out, and by blowing outdoor air into the room with said ventilation device (10), which outdoor air is heated with the thermal energy of the air which is released from the room in the room. a heat recovery cell (13) of the ventilation device (10) and in which method the input closed which is entrapped in room space t is additionally heated by a heating circuit which operates with liquid circulation after the heat recovery cell (13) before it is adjusted to the room space, of the temperature on the heating circuit with liquid circulation is performed with the control automatic (33-35) of the heating system (30-35) of a building or its equivalent so that the temperature of the intake air to be blown into the room space taken by others in a way corresponding to the temperature of the heating system. 2. A process according to claim 1, characterized in that, in said auxiliary heating circuit with liquid circulation, a liquid with low freezing point is used as a heat transfer medium. 25 3. A process according to claim 1 or 2, characterized in that the heat transfer medium is carried out by a mixture of water and glycol, industrial alcohol or the like. 30 4. A method according to any one of the preceding claims, characterized in that the additional heating circuit is heated with heat taken from the heating system (30-35) with the help of a heat exchanger (2), whereby the heat is heated. The heat exchanger is conducted to the supply air which is taken outside and which is to be vented to the room space by means of a heating cell (1) arranged in the ventilation device (10). 10 82547 5. Ventilation systems intended to carry out the process according to any of the preceding claims, which includes a ventilation device (10) arranged to suck exhaust air from the room space which is heated with a separate heating network (30-35) which is provided 33-35) and blowing outdoor air into the said room space, which ventilation device (10) is provided with a heat recovery cell (13), which is arranged to heat the input air taken out by means of heat energy from the air which is vented and vented into the air. to the room space and in which ventilation device (10) an additional heating cell (1) is arranged after the water recovery cell (13) at the flow wall for the air to be blown, which cell is arranged to heat the intake air taken out before being blown to room , which additional heating cell (1) is connected to the heating network (30-35) in series with said heating network rk by mediating a heat exchanger (2), and wherein the heating circuit formed by the auxiliary heating cell (1) and the heat exchanger (2) functions with liquid circulation, characterized in that the temperature can be controlled by heating. the automatic control of the heating network in such a way that the temperature of the intake air taken from outside and blown into the room space via the extra heating circuit and especially the heating cell is arranged to breathe in a way that corresponds to the temperature of the heating system. 25 6. Ventilation system according to claim 5, characterized in that the heat exchanger (2) of the auxiliary heating circuit Ar is connected to the supply line (31) of the heating network. 7. Ventilation system according to claim 5 or 6, characterized in that the heat transfer medium circulating in the heating circuit of the ventilation system is a liquid with a low freezing point. 8. Ventilation system according to any one of claims 5-7, characterized in that the heat transfer medium is a mixture of water and glycol, industrial alcohol or the like. Il