DE3703754A1 - Method and device for heat recovery from ventilation of preferably large rooms, factory workshops and the like - Google Patents

Abstract

The method or device serves to recover heat from ventilation of preferably large rooms, factory workshops and the like in buildings with high humidity. This occurs especially in rooms and workshops that are heated with infrared radiant heaters, and are equipped with an intake-air duct for conveying outside air into the interior of the building and an air discharge duct for conveying extracted air from the interior of the building out into the open. To be specific, the extracted air is passed through the evaporator (4.1) of a first heat exchanger (4) and then through the evaporator (5.1) of a second heat exchanger (5), being cooled in the process so that it is below the dew-point line of air. The intake air is passed firstly through the condenser (4.2) of the first heat exchanger (4) and then through the condenser (5.2) of the second heat exchanger (5), being warmed in the process. <IMAGE>

Description

The invention relates to a method for heat recovery Winching in the ventilation of preferably Open spaces, workshops and the like in buildings with ins particularly high humidity, especially with the Ventilation of rooms and halls by Infra red radiant heaters heated and with a supply air duct nal to convey outside air into the building interior such as an exhaust air duct to convey exhaust air from the Inside the building. Further concerns the invention a device for heat recovery in the ventilation of preferably large rooms, Workshops and the like. According to the aforementioned method.

The heat recovery during ventilation is particularly important if, for example, as a result of larger pollutant emissions in the rooms to be ventilated, recirculation processes, in which only the air is treated with little or no supply of outside air, i.e. when the whole is circulated The amount of air completely or at least almost completely outdoors and must be replaced by appropriate air from the outside. Such conditions are also present, for example, in the operation of infrared radiant heaters, in which ceramic plates are heated to raw embers by the combustion of a gaseous energy carrier, which then emit their energy preferably via thermal radiation to the environment to be heated. When this gas is burned, there is a considerable amount of CO ₂ and, to a lesser extent, possibly also CO, so that because of the required removal of these gases from the rooms, the aforementioned circulating air systems are eliminated. In addition, the rule applies to infrared radiation heating systems that, depending on the shape of the halls or rooms, 14 to 22 m ^{3 of} outside air per hour of kW heating power must be supplied. This makes an extraordinarily effective heat recovery from the exhaust air necessary to operate such radiant heaters with good efficiency. In addition, 1.2 kg of water are formed during the combustion of, for example, 1 kg of propane gas, as a result of which the air has an extraordinarily high relative air humidity. This water vapor carries a high heat enthalpy, which must also be recovered from the exhaust air.

The invention lies in procedural terms Task based on a method of the aforementioned To create a type that enables a particularly high  To achieve heat recovery from the exhaust air, in particular then, when the exhaust air is 100% exhaust air into the Free is carried and also the exhaust air high temperature and high humidity owns.

According to the invention, this object is achieved by that the exhaust air through the evaporator of a first and on closing that of a second heat exchanger and is cooled so that the dew point line of the air is undershot and that the supply air first through the Capacitor of the first and then over the condens sator of the second heat exchanger and he is warmed.

The progress achieved by the invention exists essentially in that in addition to the heat portion of the Air is an essential part of the ent in the water vapor retained heat enthalpy can be recovered with significant amounts of heat in particular incurred if the exhaust air is immediately out of the area of the infrared radiation heaters. Furthermore results in two-stage heat recovery over two Heat exchangers are extremely efficient. There is also the possibility of the two heat exchangers in their physical properties increase that of the respective heat recovery stage are adjusted accordingly so that they become Achieving optimal efficiency mutually  complete. This way, depending on the operating status a recovery of 25% up to 40% of the instal radiant heat output possible.

In terms of device, the task is followed solved the invention in that a first, with the Supply air duct and the exhaust air duct in thermal altern interaction standing heat exchanger is provided, its evaporator in the exhaust air duct and its condensate Tor is arranged in the supply air duct, and that a second Heat exchanger is provided, the evaporator in the Ab air duct to the evaporator of the first heat exchanger in Flow direction of the exhaust air is downstream and whose condenser in the supply air duct to the condenser first heat exchanger in the flow direction of the supply air is connected downstream.

Another advantage is that no mon exhaust chimney days, especially none Roof openings for exhaust air openings are required so that radiant heaters without flat roofs more can be installed.

In a preferred embodiment of the invention first heat exchanger formed by a heat pipe, the is capillary structured and evacuated on the inside and contains a liquid heat transfer medium, which in one continuous process on one, the capacitor bil condensed the end of the pipe, then to the other, the pipe end forming the evaporator flows there again  evaporated and finally back to the condenser flows. This heat pipe results in a simple structure and wear-free operation in the first heat recovery level sufficient efficiency. Wei ter it is recommended in the context of the invention that the second heat exchanger from a cooling unit with comm pressor is formed because in the second heat recovery Extraction level of the exhaust air is already part of the heat is withdrawn.

To the required air flow in the inlet and outlet To ensure air ducts, it is recommended that in each case from the heat exchangers to the building outside area of the supply air duct and the exhaust duct a supply air fan or an exhaust fan is arranged. This arrangement has the advantage that the fans in the area lower temperatures are used, which makes them Operation subject to less wear and tear so it is more reliable. To prevent contamination of the Heat exchanger surfaces as well as on the fans avoid it, it is further an advantage if in the supply air duct in the flow direction in front of the heat exchangers or in front a supply air filter is arranged in the supply air fan. It is also recommended that the exhaust air duct in Strö direction of the exhaust air filter in front of the heat exchangers is arranged.

In the supply air duct and in the exhaust air duct, you can choose between the condensers or the evaporators of the two heat  Exchanger a temperature sensor can be arranged so that depending on the operating and environmental conditions, the second Heat exchanger switched on or off if necessary that can. At the ends of the exhaust air that open into the open air duct or the supply air duct are expedient Outside air flaps arranged when the Device are closed.

To ent in the field of infrared radiant heating standing pollutants as well as those with high humidity to be able to discharge laden air as quantitatively as possible, it is an advantage if in the exhaust duct with each Exhaust air ducts provided because of a throttle valve flow at the other end in the area of radiation extractor hoods are connected.

In the following the invention on one in the drawing voltage illustrated embodiment explained in more detail; the only figure shows a schematic representation the device according to the invention.

The device shown only schematically in the drawing is used for heat recovery in the ventilation of preferably large rooms, Werkhal len and the like. In buildings with particularly high humidity. The device is therefore particularly advantageous when ventilating rooms and halls that are heated by infrared radiant heating. Such radiant heaters, two of which are only indicated schematically in the drawing and are designated by 1 , consist essentially of ceramic plates provided with small combustion openings, which are brought to surface temperatures of approximately 900 ° C. by burning off a gas on their side facing away from the heat radiation direction will. When burning the gas, e.g. B. propane, especially CO ₂ and to a lesser extent CO. These gases must be extracted - if possible already in the area in which they are created - and transported from the building to the outside in order to avoid accumulation in the building and thus endanger people. As a result of the air to be removed not only has a comparatively high temperature, but also has a high relative humidity, since approximately 1.2 kg of water is formed when 1kg of propane is burned, for example. Because of the resulting harmful exhaust gases, relatively high exhaust air rates are required, which, depending on the shape of the building, are between 14 and 22 m ³ per hour and kW heating cable for radiant heating. The air to be discharged therefore has a high heat content, in particular also because of the enthalpy of vaporization of the water vapor ent, which is extracted from the exhaust air for economical operation of the device and the supply air replacing the exhaust air must be supplied again.

In particular, a supply air duct 2 for conveying outside air into the interior of the building and an exhaust duct 3 for conveying exhaust air from the inside of the building are provided for this purpose. The Vorrich device contains a first with the supply air duct 2 and the air duct 3 in thermal interaction with the heat exchanger 4 , the evaporator 4.1 in the exhaust duct 3 and the condenser 4.2 in the supply air duct 2 . Furthermore, a second heat exchanger 5 is provided, the evaporator 5.1 in the exhaust air duct 3 is connected to the evaporator 4.1 of the first heat exchanger 4 in the flow direction of the exhaust air and the condenser 5.2 in the supply air duct 2 is connected to the condenser 4.2 of the first heat exchanger 4 in the flow direction of the supply air. The first heat exchanger 4 is formed by a conventional heat pipe, which is capillary structured and evacuated on the inside in a manner not shown, and which contains a liquid heat transfer medium which condenses in a continuous process at one end, forming the condenser 4.2 , at the end to the other, the pipe end forming the evaporator 4.1 flows, evaporates there again and finally flows back to the condenser 4.2 . The second heat exchanger 5 , however, is formed by a cooling unit with a compressor 5.3 . The compressor 5.3 supplies the condenser 5.2 on the hot gas side. The refrigerant flowing back from there is fed to the collector 6 , in which volumetric fluctuations are compensated for. In the filter dryer 7 , the refrigerant is cleaned and dried at the same time. A solenoid valve 8 arranged behind it is closed by a switching and control device 9 which controls the device when the system is out of operation, so that circulation of the refrigerant is prevented. A further valve 10 regulates the overheating depending on the temperature, an inspection glass 11 being used to adjust the valve 10 .

To ensure the required air exchange, a supply air ventilator 12 and an exhaust air ventilator 13 are arranged in each case in the area of the air duct 2 and the exhaust air duct 3 extending from the heat exchangers 4 , 5 to the outside of the building. These fans 12 , 13 are thus in the flow areas of lower air temperature, which ensures largely wear-free and therefore reliable operation.

To avoid contamination in the area of the heat exchanger 4 , 5 and the fans 12 , 13 , in the air duct 2 in the flow direction in front of the heat exchangers 4 , 5 or in front of the supply air fan 12, a supply air filter 14 and in the exhaust air duct 3 in the flow direction in front of the heat exchangers 4 , 5 an exhaust air filter 15 is arranged.

In the supply air duct 2 and in the exhaust duct 3, there is a temperature sensor 16, 17 between the condensers 4.2 , 5.2 and the evaporators 4.1 , 5.1 of the two heat exchangers 4 , 5 , which uses the control device 9 to switch the second on and off Allow heat exchanger 5 depending on the respective operating conditions. If the supply air temperature falls below z. B. 22 ° C, the temperature sensor 16 causes the connection device of the heat exchanger 5th If, on the other hand, the temperature measured by the temperature sensor 17 falls below a certain lower value, the heat exchanger 5 is switched off in the manner of a frost protection circuit.

Outside air flaps 18 , 19 are arranged at the ends of the exhaust air duct 2 and the supply air duct 3 , which are closed when the device is switched off.

In order to achieve the most effective possible extraction of the exhaust air, he is arranged in the area of the radiant heaters 1 from hoods 20 , which are connected to exhaust air lines each provided with a throttle valve 21 , which open into the exhaust air duct. The supply air can, as indicated at 22 , be supplied near the floor in the floor. Otherwise, the device, as indicated by the dashed lines, is controlled from a control point of view by the control device 9 .

Claims (10)

1. A method for heat recovery in the ventilation of preferably large rooms, workshops and the like. In buildings with particularly high humidity, especially in the ventilation of rooms and halls heated by infrared radiation heaters ( 1 ) and with an air duct ( 2 ) for conveying outside air into the interior of the building and an exhaust air duct ( 3 ) for conveying exhaust air from inside the building into the open, characterized in that the exhaust air via the evaporator ( 4.1 ) of a first ( 4th ) and then the evaporator ( 5.1 ) of a second heat exchanger ( 5 ) and cooled in such a way that the dew point of the air is undershot and that the supply air is first via the condenser ( 4.2 ) of the first and then via the condenser ( 5.2 ) of the two-th heat exchanger ( 5 ) and is heated. 2. Device for heat recovery in the ventilation of preferably large rooms, workshops and the like. In buildings with high atmospheric humidity according to the method of claim 1, in particular in the ventilation of rooms and halls by infrared radiation heating ( 1 ) are heated, with a supply air duct ( 2 ) for conveying outside air into the interior of the building and an exhaust air duct ( 3 ) for conveying exhaust air from the inside of the building, characterized in that a first one, with the supply air duct ( 2 ) and the Exhaust duct ( 3 ) in thermal interaction heat exchanger ( 4 ) is provided, the evaporator ( 4.1 ) in the exhaust duct ( 3 ) and the condenser ( 4.2 ) in the supply air duct ( 2 ) is arranged, and that a second heat exchanger ( 5 ) is provided whose evaporator ( 5.1 ) is connected in the exhaust air duct ( 3 ) to the evaporator ( 4.1 ) of the first heat exchanger ( 4 ) in the flow direction of the exhaust air and its condenser ( 5.2 ) in the supply air duct ( 2 ) downstream of the condenser ( 4.2 ) of the first heat exchanger ( 4 ) in the flow direction of the supply air. 3. Apparatus according to claim 2, characterized in that the first heat exchanger ( 4 ) is formed by a heat pipe which is capillary structured and evacuated on the inside and contains a liquid heat transfer medium which forms the condenser ( 4.2 ) in a continuous process Condensed tube end, then flows to the other, the Ver evaporator ( 4.1 ) forming tube end, evaporates there and finally flows back to the capacitor ( 4.2 ). 4. Apparatus according to claim 2 or 3, characterized in that the second heat exchanger ( 5 ) is formed by a cooling unit with a compressor ( 5.3 ). 5. Device according to claims 2 to 4, characterized in that in each of the shears from the heat exchanger ( 4 , 5 ) extending to the outside of the building area of the supply air duct ( 2 ) and the exhaust air duct ( 3 ) a supply air fan ( 12 ) or an exhaust fan ( 13 ) is arranged. 6. Device according to claims 2 to 5, characterized in that in the supply air duct ( 2 ) in the flow direction in front of the heat exchangers ( 4 , 5 ) or in front of the supply air fan ( 12 ), a supply air filter ( 14 ) is angeord net. 7. Device according to claims 2 to 6, characterized in that an exhaust air filter ( 15 ) is arranged in the exhaust duct ( 3 ) in the flow direction in front of the heat exchangers ( 4 , 5 ). 8. Device according to claims 2 to 7, characterized in that in the supply air duct ( 2 ) and in the exhaust air duct ( 3 ) between the condensers ( 4.2 , 5.2 ) and the evaporators ( 4.1 , 5.1 ) of the two heat exchangers ( 4th , 5 ) a temperature sensor ( 16, 17 ) is arranged. 9. Device according to claims 2 to 8, characterized in that at the ends of the exhaust air duct ( 3 ) or the supply air duct ( 2 ) from senluftklappen ( 18 , 19 ) are arranged, which are closed when the device is turned off. 10. Device according to claims 2 to 9, characterized in that in the exhaust air duct ( 3 ) each with a throttle valve ( 21 ) provided exhaust air lines, at the other end in the area of the radiant heaters ( 1 ) arranged extractor ben ( 20 ) are connected.