DE2816113A1 - Large room or cooking equipment waste heat utilising appts. - uses heat exchanger and chiller to evaporate water for cooling - Google Patents

Abstract

Gaseous source of waste energy, including heat, is passed through a gas to liquid heat exchanger and then a chiller to agitate a water bath and produce evaporation of water for cooling. The heated transfer liquid is passed through a heat exchanger to heat makeup air while, alternatively, chilled water from the chiller is pased through the heat exchanger to cool the makeup air. The source of waste energy, including heat, is normally a grease extraction ventilator mounted to receive fumes and heated air from cooking equipment. Alternatively heated air which has risen to the upper portion of a large room or enclosure, such as an auditorium, theatre, meeting hall is used. The heated air removed from such a position is adapted in part to be recirculated, but all of it may be used to furnish heat for heating fresh makeup air.

Description

Method and device for utilizing waste energy

A gaseous waste energy is produced including the heat one to a liquid heat exchanger for heating an exchange liquid and then passed through a cooling device to stir a water bath and a Evaporation of water for cooling to effect this.

The heated transfer fluid goes through a heat exchanger for heating the fresh air or the like., while also chilled water from the cooler passes through the heat exchanger to cool the fresh air. An additional warming e.g. by an oven or additional cooling e.g.

a cooling system can be used if required.

Separate heat exchangers as for separate areas can also be supplied with heated transfer fluid or cooled water.

The source of waste energy including heat is usually Smoke and heated air, as well as gases from a cooking system, produced by a grease extraction fan have been conducted. Such a grease extraction fan can have water contact devices whose water can circulate through the heat exchanger if only cooling by circulating chilled water supplied by the cooling system is desired.

Other sources of waste energy may also be suitable, e.g. heated air leading to the upper part of a large room or the like, such as an auditorium, a theater, a meeting hall or the like has risen. The heat from Air taken from such a point is partially used for recirculation, but all the air can be used to heat fresh air deliver. Several forms of refrigeration systems are used, including special dual compartment refrigeration systems as well as other ways of returning circulating water to the cooling system are described.

The invention relates to a method and an apparatus on the use of waste energy and on the alternative cooling of water for cooling of extra air.

With regard to the latter, there are numerous types of systems for Treatment of air. In some species, commonly known as 'Swamp-Kühlert' water is trickled into a stream of air or contacted by the air, by passing it through a water-absorbent pad, the air then causes the evaporation of some of the water, increasing the temperature of Air and water because of the number of units used to compensate for latent heat the VprdimDfuna of the Was.X4-rs is lowered.

For this cooling, the air should normally be relatively dry be as such a "sump cooler" with real effectiveness at excessive relative Humidity of the inlet air does not exceed 50yo. The so-called "sump cooler" is for use in places where the relative humidity of the air is low, or particularly suitable in summer when cooling is required. Obviously generated chilled air with a relative humidity normally given in a room of 10046 for people intolerance.

Among the subjects of the invention is a method and a device for utilizing the waste energy, with the exhaust air or exhaust gases in intimate Contact with water can come, what with a relative minimum effort in terms of complexity and cost. For one such procedure and one Device in which a flow of water is adapted to the volume of air or gases can be so that not only the air or the gases, but also the water is cooled and can be extracted for heat exchange with additional air, is this feature especially applicable in situations where the original air is the use as inlet air for the same or another room is not perfect. A such a case can occur when the resulting air is unacceptably high Has moisture or smoke or other substances created during cooking or the like.

contains, or is contaminated for any other reason.

Another object of the invention is a method and an apparatus, in the case of separate water baths through different exhaust air or exhaust gas flows for cooling be brought into contact with the fresh air at subsequently lower temperatures.

Further objects of the invention are a method and a device, that of a source of heated exhaust air or of heated exhaust gases, e.g. from a cooking system is assigned, and in which the air or gases after the passage on contact with water, as in a grease extraction fan according to US Pat. No. 3,841,062 for Extraction of air or gases and other cooked products through a heat exchanger for heating water or another passed through Heat exchange fluid is directed.

This heated water is used in a heating system, though the outside temperature is lower than the temperature to be maintained inside, but can even if the outside temperature is higher than the one inside to be kept after walking through the heat exchanger against fin water bath to evaporate part of the water and to cool the water. The chilled water can then be transferred to a or several heat exchangers are supplied to allow the air to be introduced into the or to another area to be cooled. This latter heat exchanger can be located at a remote location, e.g. on a roof.

The process of recovering waste energy from exhaust gas, including Heat, according to the invention, includes moving exhaust gas from the waste energy source for providing heat, moving a heat transfer fluid through the heat exchanger for heating the liquid, supplying water to a cooling system with walls and Guide surfaces for sifting the gas in a water bath, in order to stir it and to use it Evaporating the water to cool the water and gas, moving the gas through the Cooling system and to intervene in the water bath, passing through treatment air for a barely and the like through a heat exchanger, which is a way for a heated one or contains chilled liquid for heating or cooling, also the treatment air for a room or the like. Be passed through the heat exchanger that is heated Transfer fluid circulate through the heat exchanger, a cooling system Use walls and baffles to direct the gas into a water bath to stir it and the water for cooling Water and gas. to evaporate, water Deliver the waste energy air to the cooling system to obtain a water bath Heat exchanger for stirring the water bath to lead to the cooling system to the water to cool, and can also use the chilled water from the cooling system through the heat exchanger circulate. The way in which these tasks are solved and how other items and novel features of the invention will be achieved with the aid of the drawings described.

In the drawings: FIG. 1 is a vertical center section of a Exhaust water cooling system, in which separate air sources against individual water baths guided and used separately or drained while the airflow cooled Water at each point in time goes through a special heat exchanger to the air another source to cool; Figure 2 is a vertical section through a drain pipe and an overflow cap used in the water baths of Fig. 1, in a larger size Scale; Figure 3 is a vertical center section of a grease extraction fan, the is located above a cooking system and in which the exhaust air passes through after the fat removal flows through a heat exchanger and supplies hot water for heating purposes on cold days or the exhaust air after the fat removal pass through a water cooling system can to supply chilled water for air cooling on warm or hot days; figure 4 shows a plan view of the system according to FIG. 3 on a smaller scale; Figure 5 a Flow diagram with the control devices that are used with the heating and cooling system Figure 3 is used, and the heat transfer devices for the treatment air; Figure 6 is a similar flow diagram of another arrangement in which individual Air heat exchanger, supplied either with a heating or a cooling liquid can be, and also an alternative return flow arrangement for the cooling system; FIG. 7 shows a partial section of a return guide and nozzle arrangement according to FIG. 6; figure 8 a vertical center section of a grease extraction fan according to FIG. 3, but with a different water chamber, different baffles, and different overflow arrangements and especially another cooling system; FIG. 9 shows a horizontal partial section the line 9-9 of Figure 8 on a larger scale; and Figure 10 shows the diagram of a pump and control valve arrangement for two fans according to FIG. 8.

In the exhaust air or Xbgas water cooling system according to Figure 1 contains a Housing H two separate water bath chambers W and W ', the special liquid sources and exhaust air or sources of exhaust gas with inlets 10 and 10 ', which are connected to a corresponding opening in the base plate 11 of the housing are. The housing also includes side walls 12, end walls 13 and a top wall 14, which have openings for attaching two outlet lines 15 and 15 '. Between the end walls and away from the center as a divider between lines 10 and 14 10 'is a vertical plate 17, each side of which is an upright Plate 18 and 18 'is located remotely. The air or the gases on either side flow over the upper edge of the respective wall 18 and 18 ', while over this Walls at a distance a horizontal plate is attached above the divider 17 and runs between the end plates of the housing. The plate has on each edge 19 has a down flange 20 or 20 'on which an angled guide plate 21 or 21 'is adjustably attached, which has a flange 22 or 22', which is led down to the corresponding wall 18 uder 18 '.

Press plate 19, flange 20, 20 'and flange 22, 22' the air or gases between the wall 18, 18 'and the lower edge of the flange 22, 22 '. The lifting of the lower edge of the flange 22 and 22 'is adjusted so that with the respective volume of air or gases, these are attached to the upper surface of the water of the bath attacks and drives it up and away from the flange 22, 22 'so that it abuts against the respective side wall 12 of the housing.

Two removable plates are used to adjust the access to the respective Guide plate 21 or 21 '. An upright tube 25 or 25 'is at its upper end accordingly provided with a drain cap 26 or 26 'to the water depth in the respective Keeping bath at the correct level.

After being led up out of the water bath, the air or the meet Gases onto a baffle 27 or 27 'attached to the inner wall 12, respectively is, from this leads inwards and each a downwardly inclined flange 28 or 28 ' around which the air or gases are guided. Be that way Air or gases are not exposed to a stripping action that removes water droplets only by the action of the flanges 28 or 28 'on their own, but also by turning of air around gases around the flanges so that water droplets still affect the centrifugal force be thrown out.

The cooled air resp. the gas, i.e. cooled by the evaporation of water on each side of a middle Subdivision 29 to a drain line 15 or 15 'upwards, where it is used as air-conditioned Air is used in the same or in a different room, or is only vented. the Flow through the drain line 15 or 15 'can be through a conventional (not shown) Suction fan take place in an imaginary line outside the drawing.

In addition to using the resulting air, e.g. an air conditioning agent, or cooling by passing through a heat exchanger through cooled: air i.e.

from a water bath, an additional liquid serves as an additional Cooling a gas or air. That coming from the respective water baths W and W ' Chilled water is thus withdrawn via a line 30 or 30 'and through a Line 31 or 31 'returned. The withdrawn cooled fluid can in a heat exchanger E used to cool additional air will.

If necessary, treatment water can be fed through line 32 or 32 ' while each water bath is drained via a drain pipe 33 or 33 ' which is connected to the bottom of the respective bath, with the flow is regulated by a valve 34. During normal operation, the drain valve 34 is closed.

When air flowing through each exhaust line is exhausted because it is not usable e.g. because of too high humidity, the cooled air came or cold water or another heat exchange fluid can be used. Since exhaust air or exhaust gases received via the inlet lines 10 and 10 'are normally differ from other sources and after passing through the cooling system on different Ways are available, it is appropriate that that in the respective baths W and W 'chilled water can be brought to different temperatures. the Cooling effect is thus achieved by guiding treatment air through the warmer Heat exchanger E and then increased through the cooler exchanger. Also can the air that has passed through the bath W and the air that has passed through the bath W 'has been performed, have compatible properties, so that a mixture this air, even at slightly different temperatures and slightly different relative humidities still produce the desired cooling effect if they are in a special is hardly introduced without any inconvenience for people in this room develop.

The advantage of the double water bath for two air flows leading to the Inflow of air to cool the same or another room or to exit used in the atmosphere will arise when the air supply to a line, e.g., line 10, taken from the area above a sink which can generate hot air with high humidity. The one through the line 10 'delivered air can also come from an area near the washing-up facility, e.g. under this can be removed when the air can be colder and less humid By passing the high humidity air through a water bath and the air of the other source through the other bath allows considerable flexibility in the arrangement can be achieved. The cold water outlet 30 or 30 'is provided with a pump 35 or 35 'connected.

Each heat exchanger E usually has a number of turns 36, through which the liquid to be cooled from an inlet 37 to an outlet 38 with each inlet 37 connected to a pump 35 or 35 '.

The turns 36 are first in an axially spaced position brought, then a stack 39 of a loose interwoven of copper, aluminum or another material placed between adjacent turns to make the middle one as well Space inside and outside of rooms without taking up a twist. The winding structure is then compressed until the fabric 39 is deformed so that the surfaces of the turns are touched and thus a greater tendency for heat to flow out obtained between the fibers or threads of the fabric and the turns. The squeezed Tissue is underneath the coils 36 and also from a screen 40 at each end Pressure held. At the entrance of the heat exchanger E can be a conventional filter 41 are located in order to prevent crushed material in the tissue of the heat exchanger settles.

The respective heat exchangers E are located in guides 42 and 42 '. The cooled water outlet pipes 30 and 30 'can be connected to the upper ends of the respective Winding 36 may be connected, the lower end of the winding being connected to the return pipe 31 or 31 'is connected to a counterflow in each respective heat exchanger to obtain. In addition, the stream can be cooled water flowing through the pipe 30 to the incoming water pipe 31 ', for the bath W', while the bath W is used as a precooler for the bath W '. The then cooled water from the bathroom W 'can circulate from the pipe 30' through a heat exchanger to provide additional cooled Air or the same air to cool that is initially in the line from the heat exchanger has been cooled. The water released from this heat exchanger can be over the line 31 in the bath W are given. This allows maximum cooling can be obtained from the available energy.

Of course, the one supplied to bath W through line 10 can be used Air have such a high humidity that after connecting to the water bath, the humidity becomes so high that the air cannot be introduced directly into a room.

However, this does not mean that for example initial input the air does not absorb sufficient moisture through the guide 10 or 10 ' can to produce a cooling effect, but usually the opposite as the heated air with the same amount of moisture per unit of dry air has a lower humidity than the air at a lower temperature. the Heated air, e.g. from a washing-up facility, can, although it contains a significant amount of moisture owns, still absorb additional moisture up to the saturation point and the temperature of the bath against which it is directed.

One possible construction of a drain cap for the overflow pipe 25 (Figure 2) contains an inwardly directed stop 44 on the inside has a thread so that it can be adjusted on the tube 25 up and down can, and is provided with a ring series of vertical holes 45 through which water can flow off when the water level 46 goes beyond the upper part of the stop 44. Usually the water level is inclined because of the impact of air on water, so that the drain height is composed of different heights around the cap.

Normally the water level is 46 at the upper edge of the stop 44 held so that there is no leakage until the water rises. Although the Flood and the flow of water under the influence of the air flow the height 46 can fluctuate slightly, a general average height is maintained, as the water's edge in front of the pipe 25 is lower than the height 46 and the water edge behind the pipe 25, i.e. brought up to the corresponding side wall 12 'and above height 46 can be.

The device of Figure 3 serves the advantage of removing the Heat contained in air and gases above the cooking system 49, e.g. a grill or a hotplate, and the passage through a grease extraction fan with water contact means, for example, according to U.S. Patent 2,841,062, in which the air with sufficient Speed is passed against a water bath to create water eddies and to give off the fat, smoke and other substances produced during cooking, except maybe carbon monoxide and toxic gases. The cooking system and the fat removal fan V are located in front of a wall 50 with an insulating layer 51 to the Reduce the risk of fire. The air gets through as it flows through the fan V. Move around the front lower edge of the guide plate 53 against the water in one Pressed space 52 and pushes the water against a curved back plate 54, goes then a baffle flange 55 for a purpose similar to that of the flange 28 on the guide plate 27 according to FIG. After going through the grease extraction fan V exhaust air is led through a coarse filter 58, e.g. made of glass fibers, which is carried out through a Gate 59 happens, which is brought into the position shown in dashed lines for this purpose will. This air still remains warm from what has been generated by the cooking system and is passed through a heat exchanger E similar to that previously described is similar, with pipe coils and pressure against fabric made of copper or other Material or other construction can be used. This heat exchanger is with an inlet pipe 37 and an outlet pipe 38 for the heat transfer fluid, e.g. water. The flow through the heat exchanger warms them up hot air the liquid supplied from inlet 37 and exiting from outlet pipe 38, to create a countercurrent. The heated water or other liquid is discharged from the outlet pipe 38 to an air heater which is the heat exchanger E is similar, but in which air is heated for air conditioning by flowing through it and then transferred to the room to be heated. The one rising from the cooking system 49 Air or the gas goes through the fan V and can be caused by cooking odors or the like. be dirty, causing it not to be definitively delivered to a room Air can be used.

If cooling is desired, waste air and exhaust gases can still be present by the heat exchanger E for cooling the air before flowing through the cooling system C, to which water is supplied for evaporation and thus for cooling. The heat exchanger E and the cooling system C are located in a passage with a front wall 56 and a rear wall 57 and corresponding end walls. The width of the front and the back wall depends on the width of the cooking system and the number of heat exchangers E and cooling systems C from. With two cooling systems C, as in Figure 4, via two grease extraction fans V and in the series of four to six heat exchangers E under each cooling system C, the outlet 38 of each exchanger can be connected to a manifold 60, which is located on a hot water pipe 61.

Similarly, returns 37 are connected to a head piece 62 which are in communication with a return line 63, e.g., lines 37 and 38, which are connected to distributors for parallel operation of several heat exchangers.

The cooling system C according to FIG. 3 is in the function of that according to FIG the same, except for a single inlet and outlet for the same waste air and the same exhaust air and a shared bathroom. The waste air flows to each side a bottom wall 11, is supported by guide plates 19 and 19 "over upright walls 18 and 18 'and pushed into the water bath W.

The transverse plates 19 and 19 'are provided with guide plates 20 leading down and 20 ', each of which to the respective wall 18 or 18' at the lower edge leads. The water is led from each side against a central partition 24, the air then on opposite sides of the partition 28 on each side pulls upwards. The air then passes through the outlet guide 64, which is connected to the Upper part 65 of the cooling system is connected (Figure 4). The chilled water flows then from the bottom 17 of the bath or tank to a remote heat exchanger and is returned through the return line 31. As before, the water treatment pipe leads 32 to a point in the middle of the bath and into a cap 26 to the desired Adhere to the height. The front of the device is covered by a removable cover 66 locked.

The device according to FIG. 3 is also used to carry out a method according to the invention, in which the dispensed from a cooking or similar system Gases not only to save thermal energy but also to save blower energy serves. The passage of these exhaust gases through a grease extraction fan V, a gas by means of a liquid heat exchanger and water evaporative cooling system C. thus not only the exhaust gases, but also extracts heat for heating purposes while saving of heating energy as well as cooling the exhaust gases to reduce pollution. In the cooling system, the exhaust gas is evaporated at the same time as the water is cooled cooled, so that in turn the exhaust gases are cooled to reduce the heat pollution decrease while cooling the room fresh air with very little additional Operating costs takes place. As indicated, the waste air becomes during cooling from the grease removal fan V passed through the heat exchanger E to bring them before to precool the passage through the cooling system C. The heat recovered in this way can serve to preheat water for a hot water heater while it is heated Water from exchanger E through the grease extraction fan to precool the waste air can circulate before passing through the cooling system C and the entire cooling effect especially increased when the damp Temperature of the air not enters the cooling system C.

Figure 5 shows three heat exchangers E1, E2 and E3, each of which for receiving heating water from exchanger E or cooling water from the Cooling system C (Figure 3) is used. To regulate the flow of heated water to the exchangers E1, E2 and E3 are used for a valve 68 in the hot water supply duct 4 and a valve 69 in the HeiX water return line 37. In the same way, a valve 70 is in the Cooling water outlet line 30 and a valve 71 are provided in the cooling water return line 31, a measuring valve 72 being located in the additional water line 32. From the inlet pipe 75 a pump 74r is fed to which the hot water line 38 and the cooling water line 30 are connected. A bypass flow valve 76 starts the water pressure of the pump while a check valve 77 prevents backflow. A pump evacuation pipe 78 leads into a head piece 79 around the respective heat exchangers E1, E2 and E3 to be supplied with hot water or with chilled water. the Inlet and outlet flows of each heat exchanger are controlled by valves 80 and 80 respectively. 81 regulated. The heat exchangers each contain a winding 36 in which air passes through the exchanger flows in the direction of arrow 82. The exchangers E1, E2 and E3 can usually be placed in different or distant locations like there be where the air emitted from each immediately or almost immediately into the room to be heated or cooled. One of these exchangers E1, E2 and E3 can thus be provided in a separate room dedicated to this e.g. in a wall, above a false ceiling or on a roof. In particular when placed on a roof or in another place in which a heat exchanger E1, E2 or E3 can be exposed to frost temperatures, the turns of the Heat exchanger be provided with a drain valve that is outside the exchanger. A Thermostat is set so that the drain valve opens when, for example a temperature of 0 ° G is reached. The return flow from the heat exchangers takes place to a head piece 83, then through a pipe 84 and from there through the appropriate Return pipes 37 and 31, except when in the respective return line 37 to Exchanger E is a storage tank to prevent a water build-up in the event of a change in heat or To record tripping. The water bath in cooling system C works under similar circumstances as a storage tank.

In the discharge line 64 can be used to move the air through the heat exchanger E usual blowers may be provided while the blowers are used to move the air through the exchangers E1, E2 and E3 are usually located in the inlet to allow the air through to press the heat exchanger.

The heat exchanger E not only supplies hot water during operation or a fluid for heating the cold fresh air, but also cools the exhaust gases from the cooking system and thus reduce or eliminate the effect of heat pollution the kitchen exhaust system. The cooling system C also does not have the dual function only the supply of chilled water for warm fresh air but also cools the kitchen exhaust system and in turn reduces their heat pollution effect. In connection with the Device according to Figure 5 should be there an integrated air transmission system, the several appropriately arranged fans for moving the air in a housing, e.g. from one area to another to equalize pressure in the entire building.

The heating and cooling control valves, i.e. valves 68, 69 and 70, 71, can be solenoid valves so that they are operated by a Thermostat regulated that responds to the need for heating or cooling. the Valves 68 and 69 open when pump 74 is started, and thus there the thermostat recognizes the need for heating. If this need no longer exists, the pump 74 is stopped and the valves 68 and 69 close themselves. In the same way, the valves 70 and 71 are automatically opened and the Start pump 74 when cooling is required and close the valves or The pump is stopped when cooling is no longer necessary.

There can be a special heat transfer medium through the exchanger E, but in terms of the likelihood of starting and stopping the appropriate circuits that this means with water from the cooling system is mixed, water is preferred as the heat exchange medium for exchanger E. If the outside temperature is very high or very low, the heating or cooling are additionally supplied by heating or cooling systems.

The diagram of Figure 6 is similar to that of Figure 5, with corresponding Parts bear the same reference numerals.

One difference is the delivery of either heating or cooling to one of the exchangers E1, E2 or E3 individually and less in a group. That The hot water pipe 38 is thus connected to the inlet pipe 75 for the pump 74, without supplying chilled water, so that the pump 74 through an outlet pipe 78 feeds a manifold 79 ″ for hot water alone, from the hot water to one or more of the heat exchangers E1, E2 or E3 by opening the corresponding one Inlet valve is supplied.

The pump 74 can then run or be started when the inlet valve 80 to return the previously heated water after circulating through the respective Heat exchanger to the head piece 83 | is opened, from which the return flow is through the pipe 84 through the storage tank 85 and then through the inlet pipe 37 to the winding of the Exchanger E is performed. The cooling water pipe 37 runs from the cooling system C ' to an inlet line 75 'for a pump 74. Shunt valves 76 and 76 | and Check valves 77 and 77 | have the same function for pumps 74 and 74 ' like the bypass valve 76 and the check valve 77 according to FIG. 5. The pump 74 'supplies cold water to the pump outlet pipe 78' which in turn is on the cold water distribution pipe 87 lies, from the cold water to one or more selected heat exchangers E1, E2 or E3 can be given by opening the inlet valve 80 ', the Pump 74 'is started when the first valve 80' is opened or continues to run, when another valve 80 'is open. The respective outlet valve 81 'is open and leads the water after circulation through the coil of the respective exchanger to the Head piece back, which is connected to a return pipe 84, which, as described, is connected to a cooling water return line 31. The valves 68 to 72 work, as described.

Figure 6 shows another return of the water to the cooling system 0 ', which has previously circulated in one or more heat exchangers E1, E2 or E3, including changes in the design of the cooling system guide plates. The cooling system contains a base plate 11 'upright and distributed walls 18 and 18 'through which the air through the baffles 19 and 19' into engagement with the water bath between the walls 18 and 18 'at the bottom 11 similar to comes in the cooling system C according to Figure 3. The air also flows under the lower Spouts of depending flanges 20 and 20 "as previously described, but the center baffle 24 according to FIG. 3 is omitted. After churning the water bath and evaporation for cooling, the air goes to each side under the cross baffle 27 and over each Corner between a guide plate 19 or 19 'and the respective flange 20 or 20'. In addition, the return flow from heat exchangers E1, E2 or E3 goes from pipe 31 in a tube 89, which runs with a centrally on the top of the guide plate 27 Longitudinal manifold 90 is connected rather than through pipe 31 as in the case of the refrigeration system to be returned to the water bath according to FIG. A distributed arrangement Row of nozzles 91 with a 900 rotation and for creating a horizontal, wing-shaped Spray along and below the baffle 27 are above the baffle 27 (Figure 7) on the manifold 90. The side sprays from the nozzles 91 hit the Flanges 92 which are located on each edge of the guide plate 2.7, and that so on Water hitting the flanges drips or falls from the lower edges of a lower inwardly tapered grommet 93 of each flange 92 downward. That so dripping or falling water forms a thin curtain of water through which the Air or the gas to evaporate some water and further cool the rest Water passes through. A number of nozzles 91 are preferably mounted so that from the area of the outlet guide 64 sprays in opposite directions to the The end of the cooling system can be directed to create a water curtain at the Avoid leadership and reduce the amount of water that gets into the air and could be released into the atmosphere.

Such an additional evaporation of water from the curtain is beneficial if the temperature of the air hate by stirring up the water bath is not achieved and maximum cooling is desired. Indeed, the spray nozzles can 91 produce sufficiently divergent sprays that penetrate into the area between the Flanges 20 and 20 'are directed, and cover the area sufficiently to one coarse part of itift oiel (yes, let the sprinkled water come into contact with that the Querleitplatte 27 can be omitted over the bath.

During use, the heat exchangers E1 E2 or E3 passing air may only be part of the air circulating in the area to which it is delivered, e.g. in a room, because part of the air for this room was not tempered Outside air is. Typically, at least some of the incoming air should be outside air to be able to keep a reasonable oxygen delivery. There are times when the outside temperature is such that the fresh air for one or more areas neither heated or cooled. However, if warming for special weather conditions is required, such as before or during frost and the one generated by the grease extraction fans If heat is insufficient, additional heating such as bridging part of the Fresh air via a conventional air heating oven either outside of the fresh air or the fresh air that has already gone through a heat exchanger E1, E2 or E3 is to be used. An auxiliary heater can also be added to the room or area additional heat from the area through the auxiliary heater and back to the area circulating air provide additional heating. The need for additional Warming occurs when the outside air temperature drops below during bad weather a temperature which is determined by the heat that is used for the exchanger fluid is available at the exchanger. In a similar way additional cooling by mechanical cooling systems can be used during hot months when the outside temperature is high enough to allow the cooling effect of the Cooling system C or C 'supplied cold water does not provide sufficient cooling of the fresh air generated. That is, the need for additional cooling arises from the outside air temperature one that is above a temperature determined by the cooling that results from the results in chilled water on the heat exchanger. Thus, either the outside fresh air, which has already passed through a heat exchanger E1 E2 or E3 through a usual mechanical cooling system to be cooled.

Or an additional cooling system can remove the chilled water from the Cooling system continues to cool or cooling air from the room can circulate. Such an additional heating system only uses 40% of the capacity of the area needed to heat the area, without the To have waste heat recovery system according to the invention, while the additional cooling system only 50% of the capacity required to cool the area without the cooling phase of the waste energy recovery system would be necessary according to the invention. Each heat exchanger E1, E2 and E3 can have several represent individual heat exchangers in a set or a series and it can more than three separately regulated areas with heated or cooled fresh air are supplied.

The device of Figure 8 includes a modified top mounted one Fat extraction fan or two fans for taking in heated air and gas from a cooking system similar to Figure 3. This fan is with a water contact device with outwardly inclined front wall 95 provided that from fashions 96 runs upwards and has a crimp 97 on its upper edge. A row Side panels 98 are removable on the outside of wall 95 opposite openings for inspection and cleaning. Ascending from the cooking system Gases go up around wall 95 and also to a sloping back and forth Floor wall 99 of a room above the water contact device, with suction the gases through a constriction between the crimp 97 and a flange 100 that extends downward from wall 99 at a greater angle to the horizontal and from the wall 95 goes obliquely. The suction is from an exhaust fan at the end of one Guide 64 'generated which is connected to the top of the housing H'. On the flange 100 is a plate 101 adjustably attached, which is a substantially vertical Has spout 102 on its lower edge, the position of which is adjusted to and from the water bath is that in a chamber between the front wall 95, the bottom 96, a rear wall 103 is contained by the chamber and housing and corresponding end walls. When walking around around the lower edge of the spout 102 the gases are forced into engagement with the water bath, to remove fat, smoke particles and the like. Brought to the location of the spout 102 normally on the volume of gas flow both under the spout and between this and the rear wall 103 depends.

The gases also pass through a diverging throat section between the plate 101 and a forwardly inclined, angled guide plate 104 through which leads up and receives a horizontal guide plate 105, the at its front edge a downwardly running, moisture-wiping spout 106 owns. The guide plate arrangement of the water contact device according to FIG. 8 appears the To increase washing effect over lower flow areas and to be quieter in operation than the water contact device according to Figure 3. Also the The angle structure of Figure 8 is less expensive to manufacture than that curved guide plate and the plate construction according to Figure 3. The water contact device according to Figure 8 is provided with an open top part and an overflow box 107, which keeps the average water level in the bathroom within a desired range, while a dispensing tube 108 is connected to the box 107 and to a suitable one Installation point leads. The water chamber can be provided with a sump pump that has a shielded entrance sub-floor 96 at one end and out of the chamber Then supplies water to a filter to remove grease and other debris returns to the water chamber.

When dispensing from the constriction between the lip 106 and the wall 99 the gases expand into an overlying space at the rear of a wall 103, on the front side of the front wall 110 and at the ends of corresponding end walls of the housing H 'is limited to additional moisture to drop off. The front wall 110 can at its lower end with a side distributed row of removable access boards 111.

An equal set of access boards and one or more in between lying access boards 113 are at the top. The gases then go through a filter 58 which has a removable handle 59 'for inspection and cleaning possesses, and then in a heat exchanger E of the type described. In the same Fan can be one or more exchangers E, with one outlet one each is connected to a manifold 60 from which a pipe 61 extends, and one each Inlet 37 is connected to a manifold 62 which is fed by a pipe 63. A heat exchange fluid, usually water, that heats to a heat exchanger is performed, which corresponds to the exchanger E1, E2 or E3 according to Figure 5, is through the tubes 61 and 63 conveyed in the direction of the arrows.

After passing through the heat exchanger, the gases are in a Cooling system C "pulled, which is located in a room above a floor 11" Has water bath and outwardly inclined side walls 18 ".

The bottom and side walls are double-walled with insulation in between to reduce the conduction of heat on the floor and around the side walls Gases. The gases go around the top of each side wall 18 "of the water chamber and are bent downward on each side by an inclined guide plate 19 ". Each guide plate is provided with a grommet 20 "extending downwards, which in turn at a greater angle downwards, but towards the center and less towards the side walls is inclined.

These baffles and shells bring the air into engagement with the water contained in the water chamber, the height of which is 25 "from an overflow pipe, which is connected to a drain pipe 26 ". The pipe 26" leads into the fan water chamber adjacent to the drain pipe 108 and also serves another Purpose, which will be described later, while fresh water for the cooling system can be inserted through a tube 32 '. The gases that attack the water bath, stir the bath and cause the evaporation and also carry water droplets that to waste of it 8Ttlpff? \ Ersuhn. forward the phase in the area over expand the side plates 19 ″, remaining water droplets settle and fall down onto the guide plates, where they drip off the bottom edge of the 20 "flanges, to intervene with the gases. When the cooling system is used for cooling purposes the returning water is from a pipe 89 'to a horizontal manifold 90 "given, on the underside of which several nozzles 91 'are attached, from which Water into the opening between the flanges 20 "for further attack by the is sprayed down between the flanges upwardly flowing gases. This takes place a further evaporation and cooling of the water sprays, which then in a water bath drip and thus lower its temperature.

The chilled water of the cooling system collects in a box 115, which is inserted into the bottom 11 ″ and from this for connection to a pipe 116 is directed downward, the one in the tube 61 for a dual purpose connected distributor leads. When the cooling system is used for the first time and cooling water to the heat exchange devices, e.g. the exchangers E1, E2 and / or E3 is distributed, chilled water is supplied by the cooling system 0 "passed through the same pipeline that is connected to the heat exchanger E. is what simplifies the piping system. Also, if the cooling system fails is in operation and no water is returned through pipe 89 'but from the Heat exchangers E are pumped through tube 61 to a point of use and then through the pipe 63 is returned. very little water circulate from the cooling system, since the water that has flowed back through the pipe 63, the water to be heated through the Exchanger E pushes into tube 61. The connection with the box 115 of the cooling system however, prevents the accumulation of air in the pipe 61 when switching from the Exchangers E to the cooling system S "or vice versa takes place, and thus has a similar effect like the storage tank 85 according to FIG. 6.

According to FIGS. 8 and 9, the tube 116 runs from the box 115 front, while the drain pipe 26 "leads from the overflow pipe 25" to the rear. Another one Drain pipe 118 connects a point next to the box floor with the drain pipe 26 ", with a manually operated valve 119 switched on to empty the refrigeration system C ", if there is water in the cooling system that is not in use under extreme conditions Weather conditions, threatening to freeze, and the cooling system these conditions is exposed. The valve 119 is accessible via a removable board 113. if the water chamber of the fan should be emptied for this purpose, the mentioned sump pump can be used, the pump outlet connected to a drain will.

FIG. 10 shows an arrangement for regulating the optional heating the fresh air from the heat exchangers E in each of the two fans or Cooling the fresh air with chilled water from the cooling system C ". This arrangement contains the connection of the tube 61 with a pump 74 'which is in the function of the Pump 74 corresponds to Figure 5, but hot water for the heat exchanger E, as for a set of exchangers E in each of the two fans, when the fluid of the exchanger, e.g. B. water to exchanger E through the pipe 63 is returned. The pump 74 'draws chilled water the end the box 115, from the pipes 116 and from the manifold 117 when the reflux is closed by the pipe 63. In any case, the heat exchange fluid, usually water, through pipe 78 'to the heat exchanger at a point of use supplied, such as for heating or cooling the fresh air. An oil return pipe 84 'from the remote heat exchanger leads to a three-way valve 120, its inlet on the pipe 84 "and its other outlets with the pipe 63 or, a pipe 31 ' are connected. The valve 120 may be a solenoid valve that is via a push button arrangement is operated in a suitable place, e.g. on the fan controls.

If an outlet of the three-way valve 120 is on the pipe 63, this leads Return pipe 84 'to heat exchanger E. However, if the other outlet of the valve 120 is on pipe 31 ', the reflux instead leads through pipes 89', the manifolds 90 'and the nozzles 91'. A simple change can thus create a suitable arrangement similar to that of Figure 10 for controlling a single fan with multiple heat exchangers E but result in a single cooling system C '.

Although the use of waste energy from cooking systems by over one Grease extraction fan outgoing air has been illustrated and described and the Use of waste energy from air removed above and below a washing system has been heated, other sources can of course also be used. For example can be the heat contained in heated air that comes from the upper part of a large Room, such as a theater, auditorium, assembly hall or the like. Has been withdrawn is used to heat or preheat incoming fresh air when the outside temperature is lower than that observed in the room shall be. if the outside temperature is higher than that in the room, air can come from the upper Part of the room has been routed through a cooling system to water for cooling the fresh air in a special heat exchanger.

Also includes various embodiments of the invention and certain Changes to these have been shown and described, so there are other examples and modifications without departing from the spirit and scope of the invention.

Claims (33)

Claims 1. A method for recovering waste energy from an exhaust gas source characterized by: moving an exhaust gas from the source through a heat exchanger (E), carrying out a hot transfer fluid the heat exchanger to heat it up, feed water to a cooling system (C) with walls (12, 13, 14) and baffles (21, 21 ') for engaging gas with a water bath (W, W ') to stir this and an evaporation of the water To effect milling of water and gas, passing this gas through the cooling system (C) and engaging with the water bath (W), passing fresh air for one Space or the like a heat exchanger (E) that has a web for a heated or cooled liquid to heat the fresh air, heating or cooling, circulating the heated heat transfer fluid through the heat exchanger (E), and alternatively circulating the chilled water from the cooling system (C) through the heat exchanger (E). 2o method according to claim 1, characterized in that the source of waste energy contains air that carries cooked products from a hotplate and is passed through a fat extraction fan (V). 3. The method according to claim 2, characterized in that the heat transfer medium Water is. 4. The method according to claim 3, characterized in that the exhaust air is passed through a water contact device of the grease extraction fan (V) and the heat transfer water circulates to the water contact device. 5. The method according to claim 1, characterized in that the cooled Water behind the heat exchanger (E) from the heat exchanger by spraying over it the water bath (W) is returned to the cooling system (C). 6. The method according to claim 5, characterized in that at least some of the returned water forms a curtain of falling water and at least the exhaust air is pressed through this curtain. 7. The method according to claim 6, characterized in that distributed arranged, parallel curtains of falling water are provided over the water bath (W, W ') and the exhaust air is directed between these curtains and so through to the side this goes through. 8. The method according to claim 1, characterized in that the fresh air for different places to separate but corresponding heat exchangers (E) be supplied that the heated transfer fluid through heat exchangers circulates, the corresponding points of which require the fresh air to be heated, and that the chilled water from the cooling system (C) circulates through heat exchangers, that require cooling of the fresh air. 9. The method according to claim 8, characterized in that an additional Oven heating of fresh air or used air is provided, their corresponding Provide fresh air heating when the outside air is below a temperature which is exchanged through the heat exchange fluid to the heat from is available. 10. The method according to claim i, characterized in that additional Cooling is supplied by cooling fresh air or used air, their corresponding places require cooling of the fresh air when the outside air is above a temperature that is achieved by cooling from the chilled water at the heat exchanger is available. 11. The method according to claim 8, characterized in that the heated Heat exchange fluid to all individual heat exchangers at the same time Available. 12. The method according to claim 8, characterized in that the heated Heat exchange fluid or chilled water to the individual heat exchangers is provided individually. 13. Device for performing the method according to the preceding Claims having a source of waste energy containing heat and a gas-liquid heat exchanger, characterized by means for carrying a heat transfer fluid through the heat exchanger (E) for heating this, a heat exchanger with a Path for a heated or cooled liquid for heating or cooling fresh air for a little or the like. A device for guiding the fresh air through the Heat exchanger (E), a device for circulating the heated transfer fluid through the heat exchanger, a cooling system (C) with walls and guide plates for stirring a water bath (W, W ') through the air and causing the evaporation of water for cooling this and the air, a device for guiding water to the cooling system and thus for making a water bath, a device for carrying waste energy gas from the heat exchanger through the cooling system to stirring the water bath and thus for cooling the water, and means for alternatively circulating the cooled Water from the cooling system through the heat exchanger. 14. Apparatus according to claim 13, characterized in that a Grease extraction fan (V) for absorbing smoke and heated air from a cooking system and means are provided to remove the air from the location of the cooking equipment drifting through the grease extraction fan 15. The device according to claim 14, characterized characterized in that the fat removal fan (V) with a water contact device to remove grease, smoke and fumes from the heated air of the cooking system is. 16. The device according to claim 15, characterized in that the oil transfer fluid circulating through the heat exchanger is water, and that means that water to and from the water contact means the grease extraction fan (V) runs again when the chilled water is out the cooling system (C) circulates through the heat exchanger (E). 17. The device according to claim 14, characterized in that the Circulation device for the transmission liquid and the chilled water through a common pump (74) with inlet and outlet valves each for the exchanger Includes cooling system and heat exchanger. 18. The device according to claim 13, characterized in that several separate heat exchangers are provided for heating and cooling different locations, that means the heated heat transfer fluid through some of the Can circulate heat exchanger and that a device to the alternative Circulating the chilled water through one of the heat exchangers is provided. 19. The device according to claim 13, characterized in that the Cooling system has a longitudinal floor and opposite, upward-facing Has walls in which a water chamber for a water bath (W, W ') is contained, that the walls and the longitudinal panel above the walls air over each wall and into the Flow chamber of water, and that a baffle plate from the inside edge of each plate is directed downwards. 20. The device according to claim 19, characterized in that the Spray nozzles are directed at it from a point above the bath, through the gas that attacks the bathroom. 21. The device according to claim 19, characterized in that the opposite walls (12, 13) stand upright and the length plates horizontally run and the guide plates (21, 21 ') are directed to the walls to the outside. 22. The apparatus according to claim 19, characterized in that the opposite walls inclined outwards, the longitudinal plates run downwards inclined and inclined inward on the guide plates downward and inclined inward are. 23. The device according to claim 19, characterized in that the elongated, longitudinal, middle, upper Transverse plate (27) over the first-mentioned plate is provided, and downward flanges (22, 21 ') on each of the opposite side and a row of nozzles on the bottom the upper transverse plate are provided, which are arranged distributed in the longitudinal direction is and generates a lateral and a longitudinal horizontal spray, at least a portion of which abuts the flange of the upper transverse plate. 24. The device according to claim 13, characterized in that the Cooling system contains a partition in the middle of a chamber for the water bath, those from the top transverse plate to a point above the bottom of the chamber leads down. 25. The device according to claim 13, characterized in that the Edges in a floor. Inlet openings in the longitudinal direction, elongated, upright Walls as well as side, bottom and end walls are provided, those with the opposite Walls are two water bath rooms, and a first transverse guide plate running in the longitudinal direction lies over the opposite walls and baffles from the edges of the first Lower the baffle down and drive 4 ft through the inlet, and over and around around the tops of each opposing wall; that the descending Guide plates each have a lower flange that faces the corresponding one Walls are inclined and brings the air into engagement with the respective water bath, that more Querleitplatten from the side walls to a point above the respective first guide plates run inwards, and that a leading down Flange along the inside edge of each additional bulkhead is provided. 26. The device according to claim 25, characterized in that the Cooling system has a middle division that divides the inlet into two entrance passages divided and between the upright walls and up to the first transverse guide plate runs, a middle upper partition, which the space above the first transverse baffles divided and runs between and over the further Querleitplatten, and separate Contains outlets for the rooms above the further cross guide plates. 27. The device according to claim 15, characterized in that the Water contact device contains: a water chamber with an outwardly inclined front wall and upright back wall and upright end walls, one facing inwards and downwards Flange spaced above the front wall and from a point above the top the front wall extending flange that diverges from the front wall, one on attached to the flange and with it planar plate that goes up and down on the Flange is adjustable, and one from the bottom edge of the panel down and forward trending lip. 28. The device close to claim 27, characterized by one of the rear wall running forward and angular diverging from plate and flange Guide plate, a horizontal one running from the top of the angled guide plate Guide plate, a forwardly directed grommet (102) towards the front end of the horizontal guide plate and a direction with a space into which the horizontal guide plate leads, and which contains a lower wall, from the rear edge of which the flange goes down and back is directed. 29. The device according to claim 13, characterized in that the The heat transfer fluid is water and the heat exchanger is located under the Cooling system (C) is located that a feed pipe connects the heat exchanger with a pump (? 4) connects, a return pipe is connected to the heat exchanger, a lower one Part of the water bath of the cooling system is connected to the feed pipe, a cooling return pipe Water returns to the cooling system, a first pipe the pump with an inlet of the Heat exchanger connects, a second pipe goes out from the outlet of the heat exchanger and to the second pipe for alternately connecting the second pipe to the heat exchange return pipe or a valve is connected to the cooling return pipe, whereby the cooling system water to reduce the air leakage when switching the supply to the Heat exchanger takes place from heat exchange to cooling and vice versa. 30. Device according to the preceding claims, characterized in that through a cooling system having a wall and guide plates; Directing gaseous fluids to a water bath and this to stir and an evaporation of the water for cooling effecting this and the fluid through a LuSt liquid heat exchanger with Turns for the liquid, through a device for circulating the cooled Water through the coils of the exchanger and return to the cooling system, and by a device for guiding air to be cooled through the heat exchanger. 31. The method according to claims 1 to 12, for the recovery of Waste energy from two separate gas sources, each with a different temperature Contain air, characterized by: producing two separate cooling systems with Walls and baffles for directing gas and air into a water bath for stirring this and causing the evaporation of water to cool this and the gas, Direct the gases from the respective gas sources to one cooling system each, which is in the water bath supply chilled water, of which the in a cooling system but warmer than in the Another is to build two heat exchangers, each with a track for chilled water for cooling fresh air for a room or the like, circulating the cooled one Water from the bath of the two cooling systems through the respective heat exchanger, and successive routing of fresh air through the respective heat exchanger with passage through the first exchanger corresponding to the cooling system in the the warmer water is produced. 32. Device according to claims 13 to 30 with a fat extraction fan, with a passage for air and heated substances of a cooking system, which is located under the fan and marked with a water contact system by a water chamber with an outwardly inclined front wall, an upright rear wall and upright end walls, one facing inward and downward over the front wall lying flange, the one lying above the top of the front wall Body is directed backwards and diverges from the front wall, with the space forms an inlet of the passage between the front wall and the flange, one on the flange attached and with her planar plate that goes up and down on the flange is adjustable, and one directed downward and forward from the lower edge of the plate Grommet. 33. Apparatus according to claim 32, characterized in that the Fan includes: one extending from the back wall to the front and from Plate and flange diverging angled guide plate, one from the top edge the angled guide plate forward-facing horizontal guide plate, one from the front end of the horizontal guide plate descending grommet and a space containing device into which the horizontal guide plate leads, un one Wall with one of the rear edge of the flange directed downwards and backwards is.