SE0901592A1 - Method and apparatus of a ventilation device - Google Patents

Abstract

A method for heat and moisture recovery in a ventilation system comprises step night hot and moist exhaust air (4) is cooled against a condensation surface (10) in a heat exchanger (1) whereby formed condensate (12) is collected. Incoming dry and cold supply air (7) is heated on the opposite side of the condensation surface (10) and precipitated condensate (12) is distributed and the supply air (7) as an aerosol (13) at the inlet (8) of the heat exchanger (1) for supply air (7). The atomization is done by means of a piezoelectric fog generator (15). A device for heat and moisture recovery in a heat exchanger (1) in a ventilation system has a condensing surface (10) in the exhaust air side (2) of the heat exchanger (1) and a collection device (11, 14) for condensate (12). At the inlet (8) to the supply air side (3) of the heat exchanger (1), a piezoelectric fog generator (15) is arranged, which is fed with condensate (12) and which emits an aerosol (13) of water to the inlet (8). Fig. 2

Description

l0 2 If wetting of the heated outdoor air is to take place, this means a fairly large energy supply, since the supplied water must be evaporated by supplying steam-generating heat.

It is previously known heat exchangers where the separation wall between the hot and cold side of the heat exchanger is moisture-permeable and can, for example, contain a salt that binds the moisture.

The moisture travels through the wall and is supplied, at least in part, to the supply air.

A heat exchanger of this kind cannot be regulated with regard to the humidification of the supply air, which is why significant problems can arise in certain weather situations. Furthermore, the moisture transition in a heat exchanger of this kind is imperfect in that most of the moisture precipitation from the exhaust air side takes place in the coldest part, where the air on the other side of the heat exchanger wall has a low moisture absorption capacity due to its low temperature.

OBJECTION OF THE PROBLEMS The object of the present invention is to design the method initially indicated so that a humidification of the supply air can take place using the heat content of the exhaust air for evaporation. The invention also has the ultimate goal of designing the procedure so that there are good opportunities for accurate regulation of the relative humidity in the supply air and, in addition, good opportunities for cleaning.

With regard to the device, the purpose of the invention is to design it in such a way that an analogous objective is achieved.

TROUBLESHOOTING The object underlying the invention is achieved with respect to the process if this is characterized in that the moisture is bound by condensation in the exhaust air side of the heat exchanger, that precipitated condensate is collected, that at least part of the condensate is distributed in an aerosol and is supplied to the supply air in or at the supply air side of the heat exchanger. The object underlying the invention is achieved with respect to the device if it is characterized in that the means for binding and transferring moisture comprise a condensing surface cooled by the supply air in the exhaust air side, collecting and conducting means for collecting the condensate, a non-distributing device for dispensing the condensate. a mist of small, airborne water particles in the liquid phase, the collecting and conducting means being arranged to deliver condensate to the distribution device.

COMPILATION OF DRAWING FIGURES The invention will now be described in more detail with reference to the accompanying drawings. In these: Fig. 1 shows a schematic view of a heat exchanger according to the prior art; fi g 2 the heat exchanger according to fi g 1, however modified according to the invention; and fi g 3 a lower part of a slightly modified embodiment of the heat exchanger according to fi g 2.

PREFERRED EMBODIMENT I fi g 1, the reference numeral 1 refers to a heat exchanger which operates in countercurrent and which has an exhaust air side 2 and a supply air side 3. The exhaust air side can also be called the friend side of the friend exchanger and the supply air side its cold side. The exhaust air 4 flows according to the arrows from above and down in the fi gure from an exhaust air outlet 5 to an exhaust air outlet 6. Correspondingly, the supply 7 flows according to the dashed arrows in the direction from below from a supply air inlet 8 in the direction upwards to a supply air outlet 9. The partition wall 10 side 2 and supply air side 3 consist of a heat-conducting material which is gas-tight and impermeable to water, such as copper, aluminum or certain plastic grades. The wall thickness is so small that you can call the wall a foil.

If it is assumed that the incoming supply air 7 at the supply air inlet 8 is 0-degree and has a relative humidity of 80%, then at least the lower parts of the partition wall 4 will have a temperature close to 0 °. If then the incoming exhaust air is assumed to have a temperature of 22 ° and a relative humidity of about 50 °, then a condensation will take place against the partition wall 10, at least at its lower parts. In this way, the partition wall also constitutes a condensation surface, where the reference numeral 12 indicates drops of precipitated condensate, ie distilled water. Under the given humidity and temperature conditions, as much as 6 g of water per m3 of exhaust air flowing through can be precipitated in the form of a condensate, which is collected in a collector 11 and which has traditionally been drained to a drain.

With the above temperature and humidity conditions, the supply air departing from the supply air outlet 9 will have a temperature close to 20 ° but a relative humidity which has drastically decreased below the original 80% to a value in the order of%.

In Fig. 2, the heat exchanger in Fig. 1 has been supplemented for the practice of the invention. Corresponding details have corresponding reference numerals in the two figures.

In the embodiment according to fi g 1, the collector 11 ends in a drain for receiving the condensate. In the embodiment according to fi g 2, a distribution device or more simply a mist generator 15 has been added, which has the property of distributing water in the liquid phase to extremely small, air-borne particles in the liquid phase, ie an aerosol. The fog generator thus produces a water mist 13, where the individual water particles are so small that they do not adhere to the surfaces that they may encounter and further remain floating in the air for long periods of time. Furthermore, the mist generator 15 has a line connection with the collector 11, so that at least a part of the condensate can be transferred to the mist generator 15 via its inlet 14. Because the mist generator drain for mist 13 is located at the inlet 8 to the heat exchanger side 3 of the heat exchanger, the floating water particles in the aerosol or mist 13 to follow the flow according to the arrows 7, so that the temperature gradually rises and so that there is a drying of the small water particles. In this case, the steam generating heat is taken from the heat emitted from the exhaust air 4 in the exhaust air side 2 of the heat exchanger.

Because the mist generator 15 is placed in the manner shown, the process can be controlled in such a way that no water particles in the liquid phase remain in the supply air 7 at its outlet 9.

This gives the advantage that bacteria cannot be spread into the space to which the supply air is released.

The temperature and humidity conditions given above are representative of the winter climate in southern Sweden. During other seasons, there may be a reason not to humidify the incoming outdoor air to the same extent as during the winter climate. For this reason, the line connection between the collector 11 and the fog generator 15, in particular its inlet 14, has a control equipment by means of which the fate can be regulated or completely interrupted. Correspondingly, the mist generator 15 itself is connected to a control system by means of which the amount of mist emitted per unit of time can be controlled depending on the relative humidity in the space to which the supply air is emitted.

The mist generator 15 can be of different types and comprise a sputtering nozzle, which is fed with water under high pressure. Another option may be to distribute incoming water to the fog in question by means of compressed air or by means of a rotating disc or a cup. However, the most practical fog generator should be a fog generator, with a piezoelectric plate 16, which is supplied with high-frequency alternating voltage.

Regardless of the mode of operation of the fog generator, it is important that the airborne water particles are small, less than 100 μ and preferably in the size range 3-20 u.

Because the water with which the mist generator 15 is fed is a condensate, it is free of dissolved salts as is usually present in tap water. This means that no precipitation of salt particles in the air can take place as the condensate is pure distilled water.

Fig. 3 shows on a larger scale the lower part of a heat exchanger made with an example of a piezoelectric fog generator 15. In Figs., A piezoelectric plate has been given the reference numeral 16 but its line connections to a source of alternating voltage are not shown. In fi g 3, the collecting and conducting means 11, 14 have also been given a somewhat armor-constructive design than that shown in fi g 2. It appears from fi g 3 that a level 6 regulation can take place in the water tank 17 which is included in the mist generator 15. Furthermore, the arrows 13 illustrate the outgoing water mist or aerosol.

In order to distribute the outgoing water mist 13 as well as possible in the entire air flow in the incoming supply air 7, a mist distributor 18 is arranged at the supply side inlet 8, which disperses the mist and creates turbulence.

Claims (9)

10 15 20 25 30 PATENT REQUIREMENTS A method for transferring heat and moisture from exhaust exhaust air (4) to incoming supply air (7) in a ventilation device, comprising the steps of: removing heat from the exhaust air in an exhaust air side (2) in a heat exchanger (1), at least partially transferred to the supply air (7) in a supply air side (3) in the friend exchanger, and that moisture carried by the exhaust air is bound in the exhaust air side and at least partially supplied to the supply air, characterized in that the moisture is bound by condensation (12) in the heat exchanger side (1) of the heat exchanger (1). 2), that precipitated condensate is collected, that at least a part of the condensate is distributed into an aerosol or mist (13) of small, airborne water particles in the liquid phase and supplied to the supply air (5) in or at the supply air side (3) of the heat exchanger (1). Method according to Claim 1, characterized in that the mist (13) is supplied at the inlet (8) to the supply air side (3) of the heat exchanger (1). Method according to claim 1 or 2, characterized in that the water particles of the mist (13) are given a size <100u, preferably in the range 20-3 p. Method according to one of Claims 1 to 3, characterized in that the mist (13) is generated by means of a piezoelectric plate (16), which is kept immersed in the condensate and which is operated with a high-frequency alternating voltage. Method according to one of Claims 1 to 4, characterized in that the supply of mist (13) is regulated as a function of the relative humidity in the space to which the supply air is discharged. Device for transferring heat and moisture from exhaust exhaust air (4) to incoming supply air (7) in a ventilation device, comprising: a heat exchanger (1) with a supply air side (3) and an exhaust air side (2) and means for binding moisture and at least partial transfer of this to the supply air, characterized in that the means for binding and transfer of moisture comprise a condensation surface (10) cooled by the supply air (7) in the exhaust air side (2), collecting and conduit means (11, 14) for collecting the condensate, a dispensing device (15) for dispensing the condensate into an aerosol or mist (13) of small, air-borne water particles in liquid phase, the collecting and conduction means being arranged to dispense condensate to the dispensing device . Device according to Claim 6, characterized in that the outlet for the mist (13) of the distribution device (15) has a flow connection with the inlet area (8) of the supply air side (3). Device according to Claim 6 or 7, characterized in that the distribution device (15) comprises a piezoelectric plate (16) which has a wired connection with a source of high-frequency alternating voltage. Device according to one of Claims 6 to 8, characterized by a control device which uses as an input signal the relative humidity or a parameter representing it in the space to which the supply air is supplied, and which is arranged to control the operation of the distribution device (15) or the supply. of condensate thereto for controlling the relative humidity in the space to which the supply air is emitted, to a value which is perceived by the mermaid as pleasant.