DE19750838A1 - Heating process for cavities in buildings - Google Patents

Abstract

The heating process involves mixing preheated fresh air with part of the exhaust air in a heat exchanger (3), before heating it. The mixture is divided and taken through two parallel sorption stores (5A, 5B) with heat registers, one of which regenerates the sorption mass. The warm air from the other one is dried and supplied to the building cavity. The air mixture from the heated sorption store is partly mixed with the mixture of fresh and exhaust air. The functions of the two sorption stores are changed with each other from time to time.

Description

The invention relates to a method and an installation for warm air heating of rooms in buildings where one passes air to be heated over heating register and at which can be recovered from exhaust air by using fresh air drawn in outside in a heat exchanger, through the exhaust air discharged into the free atmosphere flows, preheated.

Such a method and various according to it Process plants are known. The we The degree of heat recovery depends on the quality and number of heat exchangers used, which transfer heat with convection. The technology has in In the course of development the efficiency by refining can improve the facilities for this purpose, nevertheless considerable amounts of heat are lost. This The type of heat recovery is not optimal.

A major disadvantage due to Konvek tion working heat exchanger, it is also that  Outside temperatures are not deep below freezing work because the heat is brought into the heat exchanger Exhaust air from the heated room also a certain one Has moisture content. This moisture beats settles in the heat exchanger as condensed water and freezes here, which means the heat exchanger has no exhaust air lets more through.

For heating the air used to heat the room different heat sources are distinguished degrees of use. These heat sources generate the heat from primary energy, mostly from solid, liquid or gaseous fuels, then Heat exchangers with their limited efficiencies Transfer of heat from the fuel gases for heating the room air is necessary, or secondary energy, mostly electricity, which is expensive, or waste heat Power plants and industrial plants, which are cheap, however is usually not transportable to the place of consumption. Like this with can improve the use of heat generated only by increasing the efficiency of the necessary Heat exchangers in the area of heat transfer from the Fuel gases on the heating air and from the into the free Exhaust air discharged to the atmosphere let fresh air take place. Such improvements the efficiency of heat exchangers are at State of the art very expensive and hardly possible.

A newer type of warming has also become known of indoor air that works with sorption stores. In A sorption storage is air that this storage flowed through, dehumidified and by the damp Activity recording of the sorption stored in the store  materiales this and with this the through the store flowing air heated. The regeneration of these Saving stored sorption material can be done with billi low waste heat or inexpensive night-time electricity. Heating and regeneration can take place at different times be performed. For heat recovery from in Free atmosphere of exhaust air is such Sorbent material has not been used so far.

The invention avoids the disadvantages of the prior art Technology.

It is the object of the invention to create a new one very effective way of heat recovery too create that even at very low outside temperatures works effectively.

The invention is that one in the heat rope preheated fresh air before heating it part of the exhaust air mixes that this Luftge mix divides and by two parallel, with Sorption stores equipped with heating registers, one of which is a sorption storage for the purpose the regeneration of the sorption mass by means of its Heating register heats that one from the other Sorption storage escaping due to moisture removal train in this heated air mixture to heat the the room directs that from the heated sorpti air storage leaking at least to one Part in the air mixture of fresh air and exhaust air mixes and that one the function of the two sorption memory interchanged from time to time.

In this way it is possible to heat with an even better efficiency than previously used heat exchangers  recover high quality.

The plant for the implementation of this procedure draws is characterized by

You can use this system for the implementation of the Switch process in three variants that are special are advantageous:

In a first variant, you do that Fresh air exhaust air exiting from the mixing chamber mix divides and part into the sorption stores, the other part via the heat exchanger into the free Atmosphere.

In a second variant, one proceeds in such a way that one Luftge emerging from the heated sorption storage mix divides and part into the air mixture Fresh air and exhaust air mixed in and the other part through the heat exchanger and then into the derives a free atmosphere.

In the third variant, one proceeds in such a way that one from the moisture absorbing and therefore air exiting air mixture divides, a part into the room to be heated and the other part of the room to be heated if heating radiator and then through the heat rope and then into the free atmosphere tet.

That you can recover heat in this way and that moreover with an even better efficiency than  previously used high quality heat exchanger is over surprising, especially since procedural steps were carried out here which are so unusual that nobody would do:

It is unusual to have exhaust air with its relatively high Moisture content in the regeneration state where the moisture should be expelled conduct, because this air is cooled by the Dehumidification rather left water in the storage tank to be carried out.

It is unusual that one in the sorption storage too heating air mixture simultaneously through both the air heating by dehumidification as well through the regeneration sorption storage conducts, because how should air with one and the same moisture the moisture content in one store lieren in which other absorb moisture.

It is unusual that you do not have just heated air can enter the room to be heated, but in derives the free atmosphere.

However, these unusual features lead to the equally unusual technical success,

• - That the heat exchanger to very low tempera remains operational because there is nothing in it Water precipitates and freezes, because the Air passing through the heat exchanger is dry and hot,
• - That the room air loaded with moisture in the Memory in the regeneration state  Water loses because of the water in the tank Sorption mass up to a temperature by hot tongue is heated, in which it is only water relinquishes but does not absorb
• - That the moisture-laden air from the in Regeneration state available memory their directly following path through the other storage under dehumidification now is heated.

The trick of this type of heat recovery is in that the moisture contained in the air not released into the free atmosphere, but in System is kept and only dry air as exhaust air after being released into the free atmosphere in a conventional heat exchanger the main part of the Heat is withdrawn, which is possible because the Temperature difference between exhaust air and fresh air is always high.

This method is using a heating system of rooms in buildings that consist of at least two using a heating register to heat the Sorp tion mass equipped and thereby regenerable Sorption accumulators, pipes and valves, one to the fresh air supply leading to the sorption stores tion, one of the sorption stores in the to heating room leading supply air line and one the exhaust duct leading out of the room and a Exchanger exists in which exhaust air gives off heat, which is absorbed by the fresh air, and which is characterized in that the fresh air supply and the exhaust air pipe open into a mixer that the end  the mixer two parallel arranged Sorption storage are downstream that the two Sorption storage simultaneously from that from the mixer coming air mixture are flowed through that the output on the one hand, the air mixture through the removal of moisture heating sorption storage to one in the be heating room leading pipeline, and that the out other in the regeneration state Sorption storage to an air mixing device for Mixing of the exiting moisture-laden Air with that entering the sorption storage Air mixture of fresh air and exhaust air connected is.

This system and this ver work particularly well drive when you have the sorption mass in the heated Sorption storage brings up to a temperature and up this holds at which the sorption mass is not moist more from the air flowing through the storage records. Is the temperature of the sorbent somewhat underneath, the process still works, but not as good anymore, the required sorption mass gets bigger and their dehydration no longer so effective.

In terms of energy, this process is particularly cheap, if you look out of the heated sorption storage entering moisture-laden air through the injector initiates into the other sorption storage, because then you save a fan and that in this consumption te energy.

With this method, there may be conditions in which  it is beneficial to exhaust air through before the cycle to ent the sorption storage in the free atmosphere to let. This is done so that you get out of the mixer for fresh air and exhaust air exits and conducts only a part into the sorption storage conducts the other part through the heat exchanger and into the free atmosphere.

With this process, the moisture of the Air in the cycle, it is often still through the Au Keep people in the heated room damp activity introduced into the cycle. Still can due to leaks in the heated room and others Reasons deficits in moisture content arise that can be compensated for by the fact that in circulating air humidified in this system. This can be easiest by using a humidifier achieve, preferably in the fresh air mixer air is installed.

In this method, in which one expediently in the air intake and exhaust at regular intervals to and from the sorption stores by switching previously the air heating by dehumidification serving sorption storage of the regeneration and the previously regenerated sorption storage for air heating, you have the amount of sorption mass in the sorption stores for the respective work sufficient periods to be measured.

If an injector is provided, that of the mixer coming and directed to the sorption stores Air mixture is flowed through, this sucks from the  Sorption storage leading into the free atmosphere Line air and mixes it with the air mixture Fresh air exhaust air.

In a particularly simple embodiment, the Be equipped with a single blower, which is between the output of the mixer and the on is arranged to the two sorption stores.

To achieve a more refined regulation of this system However, it is useful if the system with two Ge blow into the fresh air and Exhaust air lines is equipped.

Through a special arrangement of the two sorption memory in angular form, it is possible that at the exit the sorption storage arranged a single valve with which the one of two sorption spouts to the supply air duct, the other to the duct Heat exchanger pipe leading to the free atmosphere can be connected alternately.

For operating the system at very low temperatures and in the event of incomplete moisture distance from the to release into the free atmosphere certain air it may be appropriate if at the from the fresh air inlet to the pipe leading to the mixer line a bypass line bypassing the heat exchanger is arranged.

The essence of the invention is based on an in the drawing shown schematically  game explained in more detail. Show in the drawing

Fig. 1 is a block diagram of a system blower with a Ge,

Fig. 2 shows the block diagram of the system of in front of the Sorptionsspei Chern air into the atmosphere is branched Fig. 1 in a circuit,

Fig. 3 shows the block diagram of the system of FIG. 1 is branched off in a circuit in the Sorptionsspei manuals in the heated air into the atmosphere,

Fig. 4 shows the block diagram of the system of FIG. 1 in a circuit in which is in the Sorptionsspei Chern heated air into the atmosphere branched, but is previously used for space heating,

Fig. 5 is a calculation of the heat recovery in the system of Fig. 2,

Fig. 6 Blaesen a block diagram of a system with two Ge,

Fig. 7 is an Hx diagram.

The system according to the invention is located in a building to be heated. Through the entrance 1 exhaust air from the building enters the system, through the entrance 2 fresh air from the free atmosphere. Both the exhaust air and the fresh air are sucked into the system by means of a fan 13 . The exhaust air entering the building from the entrance 1 passes through the filter 10 and passes through the pipe 26 into the mixer 4 , the fresh air entering the system through the input 2 flows through the filter 12 and then a heat exchanger 3 of conventional design, to gelan through the pipe 25 also in the mixer 4 gene. In the heat exchanger 3 , the cold fresh air is preheated by warm air flowing in the pipe 18 to get through the outlet 23 into the free atmosphere. In the mixer 4 , exhaust air from the room to be heated and fresh air are mixed together. This air mixture has a higher temperature than the preheated fresh air and a higher moisture content than the fresh air.

Behind the mixing chamber 4 , the blower 13 is arranged in the pipeline 30 , which leads to a sorption system consisting of two sorpti 5 . Due to the negative pressure generated by the fan 13 , which continues into the mixing chamber 4 and the pipes 25 , 26 , the exhaust air from the heated room is sucked in through the inlet 1 and the fresh air from the free atmosphere through the inlet 2 . By the pressure generated by the fan 13 , the air mixture from the Mischkam mer 4 in the sorption system with the two sorption stores 5 A, 5 B is pressed. This air mixture from the mixing chamber 4 enters the antechamber 6 of the sorption system in front of the sorption stores 5 A, 5 B and simultaneously passes through these two sorption stores 5 A, 5 B.

In sorption 5 A through which the Sorptionsmasse is heated to a temperature of about 60 ° C are heating pipes 29, which heat the 5 A lying in memory Sorptionsmasse charged with egg nem heating medium. The air mixture flowing through the memory 5 A cannot give off any moisture to the sorption mass at this temperature, because the sorption mass does not absorb any moisture at this temperature. However, the air mixture flowing through the 5 A reservoir takes with it further moisture released by the sorption mass at this temperature, in spite of a moisture content present at the entry. From the storage 5 A, the air laden with moisture passes through the pipeline 20 and the valve 21 into an injector 14 which is arranged in the pipeline 30 leading from the mixer 4 via the blower 13 into the antechamber 6 of the sorption system. In this injector, a mixing of the exhaust air / fresh air / air mixture from the mixer 4 with moisture-laden air from the room 8 is carried out. Part of this air mixture continues to flow in the circuit sorption storage 5 A - room 8 - line 20 - injector 14 - anteroom 6 - sorption storage 5 A.

The other part of the air mixture in the antechamber 6 flows through the other sorption storage SB. In this Sorp tion storage 5 B is dry (regenerated) sorption mass. This part of the air mixture releases part of its moisture and is heated by the sorption mass. This part of the Luftgemi cal gets after passing through the Sorptionsspei chers 5 B in the room 7 behind the sorption memory 5 B. The heated air emerging from this room 7 passes as supply air through the outlet 9 in the room to be heated. The amount of air entering the room to be heated can be set by means of a valve 17 ( FIG. 6).

In the circuit of this system according to FIG. 2, the air provided for the exit into the free atmosphere leaves behind the mixer 4 before the point at which air from the sorption store 5 A reaches the injector 14 , the line leading to the sorption stores 30 . it is passed through the heat exchanger 3 in which it loses heat to the supplied fresh air and discharged downstream of the heat exchanger 3 through the outlet 23 into the free atmosphere.

In the circuit of the system of FIG. 1 shown in FIG. 3, a portion of the air which is highly heated in the sorption store 5 B and is intended for space heating is branched off through the line 18 before entering the space to be heated and via the heat exchanger 3 and Exit 23 released into the open atmosphere. However, this only occurs at particularly low outside temperatures, if in other circuits condensation water m heat exchanger 3 would freeze and block the air outlet.

If there is no danger of freezing of condensed water in the heat exchanger 3 , the valve in the pipeline 18 is closed and valve 34 is opened in the circuit shown in FIG. 4, so that the part of the air to be discharged into the free atmosphere flows through the radiator 35 and additionally warmed the room. In this embodiment, the system is left by cool air with a low moisture content.

In this circuit of the system, the radiator 35 can also. Heat pipe 26 in which the exhaust air emerging from the room is conveyed. This then enters the mixer 4 at an elevated temperature, which then leaves an air mixture at an elevated temperature in order to be further heated in the sorption stores.

The moisture balance is mostly balanced. The fresh air drawn in from the free atmosphere contains little moisture, and the exhaust air returned to the free atmosphere also contains, if perhaps somewhat more than, the fresh air drawn in. A compensation comes from the people present in the heated room. If the moisture balance shows too little moisture, the air humidifier 24 can compensate for this. In the exemplary embodiment shown, this is arranged in the mixing chamber 4 . But it can be arranged at any position, z. B. also in the injector 14.

From time to time, when the storage tank 5 B is loaded with moisture and the storage tank 5 A is dehumidified, the function of the storage tanks is changed. This is done in that the heating medium previously heating the storage 5 A is now passed more through the storage 5 B and the valve flap 16 which is pivotable about the axis 16 and is arranged in the wall 28 is pivoted so that the storage 5 A Air flowing through to the outlet 9 and into the line 18 flows, while the air flowing through the memory 5 B flows into the line 20 . After a certain time, with 5 A loaded with moisture and 5 B with dehumidified storage, the memory will be replaced in their function. This exchange can take place at fixed intervals or based on moisture measurements in the storage tanks.

Fig. 5 shows another system that works according to the invention. The same components as in Fig. 1 are given the same reference numerals. In this two blowers 13 are provided, one located in the leading from the exhaust input 1 to the mixer 4 pipe 25, the other in the shear from the fresh air inlet 2 to the Mi 4-leading pipe line 26. From the mixer 4 introduces an additional conduit 32 via the valve 31 in line 18 , which leads to the free atmosphere. Through this line, additional room exhaust air from input 1 can be discharged into the free atmosphere at a temperature reduced by the fresh air admixture.

In this exemplary embodiment, the line 27 leading out of the space 8 initially leads into the line 18 , in which a valve 19 is provided between the line part coming from the space 7 and the junction of the line 27 into the line 18 . From the line 18 , a line 20 provided with a valve 21 leads to the injector 14. Through this line 20 , air is returned from the storage 5 in the regeneration state into the antechamber 6 of the sorption system. The Lei device 18 is then shear 3 before it enters the Wärmetau with an additional valve 22 .

It is possible to replace the injector 14 and the valve 21 with a blower.

The high energy recovery can be seen from FIG. 6 and can be read from the HX diagram of FIG. 7. An examination of the conditions in one and the same building has shown that the heating energy to be used in a conventional heating system with heat recovery was 12.66 KW, but only 3.33 KW when using the method according to the invention. A calculation carried out confirmed the measurement.

Reference list

1

Exhaust air inlet

2nd

Fresh air entrance

3rd

Heat exchanger

4th

mixer

5

Sorption storage

6

Space in front of the sorption stores

7

Room with hot air

8th

Room with moisture-laden air

9

Heated air outlet

10th

Air filter

11

Valve

12th

Air filter

13

fan

14

Injector

15

Valve flap

16

Axle of the valve flap

17th

Valve

18th

Pipeline

19th

Valve

20th

Pipeline

21

Valve

22

Valve

23

Exit to the free atmosphere

24th

humidifier

25th

Pipeline

26

Pipeline

27

Pipeline

28

partition wall

29

Heating register

30th

Pipeline

31

Valve

32

Pipeline

33

Pipeline

34

Valve

35

radiator

36

Valve

37

Pipeline

Claims (17)

1. Method for warm air heating of rooms in buildings, in which air to be heated is passed through heating registers and in which heat is recovered from exhaust air by fresh air drawn in from outside in a heat exchanger through which exhaust air discharged into the free atmosphere flows, preheated, characterized ,
that the fresh air preheated in the heat exchanger is mixed with part of the exhaust air before it is heated,
that one divides this air mixture and passes through two sorption stores arranged in parallel and equipped with heating registers, of which one sorption store is heated by means of its heating register for the purpose of regeneration of the sorption mass,
that one escapes from the other sorption storage, by removing moisture in this heated air mixture into the room to be heated
that one at least partially mixes the air mixture emerging from the heated sorption storage into the air mixture of fresh air and exhaust air
and that one interchanges the function of the two sorption stores from time to time. 2. The method according to claim 1 characterized,  that the sorption mass in the heated sorption brings to a temperature and on this holds at which the sorption mass is not moist more from the flow through the storage Takes in air. 3. The method according to claim 1, characterized, that one exits from the mixing chamber Fresh air-exhaust air mixture divides and part into the sorption stores, the other part about the Conducts heat exchanger into the free atmosphere. 4. The method according to claim 1, characterized, that you get that from the heated sorption storage escaping air mixture divides and part in the air mixture of fresh air and exhaust air mixes and the other part through the heat rope sher leads and then into the free atmosphere derives. 5. The method according to claim 1, characterized, that the moisture absorbing and thereby exiting air-warming sorption storage dividing air mixture divides a part into the heating room and the other part about the radiator to be heated also and then through the heat exchanger and then into the free atmosphere. 6. The method according to claim 1,  characterized, that one from the heated sorption storage escaping moisture-laden air Injector effect in the other sorption storage initiates. 7. The method according to claim 1, characterized, that the air supply and -discharge to and from the sorption stores changes by doing the air heating beforehand due to moisture-absorbing sorption spit subject to regeneration and the previous one regenerated sorption storage for air heating uses, and the amount of sorbent in the Sorption storage for the respective working hours rooms sufficiently dimensioned. 8.System for heating rooms in buildings, consisting of at least two sorption stores equipped with a heating register for heating the sorption mass and thereby regenerable, pipes and valves, a fresh air supply line leading to the sorption stores, one of the sorption stores in the ones to be heated Space-leading supply air line and an exhaust air line leading out of the room, as well as a heat exchanger in which exhaust air emits heat that is taken up by the fresh air, characterized in that
that the fresh air supply line ( 25 ) and the exhaust air line ( 26 ) open into a mixer ( 4 ),
that the output of the mixer ( 4 ) is followed by two sorption stores ( 5 A, 5 B) arranged parallel to one another,
that the two sorption stores ( 5 A, 5 B) are simultaneously flowed through by the air mixture coming from the mixer ( 4 ),
that the output of one of the air mixture, which heats up by removing moisture, sorption storage ( 5 B) to a pipe leading into the room to be heated,
and that the output of the other in the regeneration state sorption storage ( 5 B) is connected to an air mixing device for mixing the moisture-laden air coming out with the air mixture entering the sorption storage ( 5 ) from fresh air and exhaust air. 9. Plant according to claim 8, characterized in that behind the mixing chamber ( 4 ) from the in the sorption storage ( 5 ) leading line ( 30 ) branches off a pipe ( 37 ) leading into the heat exchanger 3 and then into the free atmosphere Pipeline ( 18 ) leads. 10. Plant according to claim 8, characterized in that behind the heated sorption storage ( 5 A) from the leading into the space to be heated Lei device ( 30 ) branches off a pipe ( 18 ) which in the heat exchanger 3 and then in the free atmosphere leads. 11. Plant according to claim 8, characterized in that behind the moisture-absorbing and since air-heating sorption storage ( 5 B) from the pipe leading into the room to be heated, a pipeline ( 18 , 37 ) branches off, which leads to the one to be heated Space also heating radiator ( 35 ) and then through the heat exchanger ( 3 ) and then into the free atmosphere. 12. Plant according to claim 8, characterized in that an injector ( 14 ) is provided, which forms the air mixing device and the flow of the coming from the mixer ( 4 ) and to the Sorptionsspei chern ( 5 ) is passed and from which the in Sorption storage ( 5 A) in the regeneration state draws in air and mixes it with the fresh air / exhaust air mixture. 13. Plant according to claim 8, characterized in that the plant is equipped with a single fan ( 13 ) which is arranged between the output of the mixer (4) and the input to the two Sorpti onsspeicher ( 5 ). 14. Plant according to claim 8, characterized in that the system is equipped with two fans ( 13 ) in the fresh air ( 25 ) and exhaust air lines leading to the mixer ( 26 ). 15. Plant according to claim 8, characterized in that the mixer ( 4 ) has two outputs, one output leading to the sorption stores ( 5 ) and a second output leading into the exhaust air duct ( 18 ) leading via the heat exchanger ( 3 ) ) leads 16. Plant according to claim 8, characterized in that a Ven valve ( 15 ) is arranged at the output of the sorption memory ( 5 ), with which one of two sorption memories ( 5 A, 5 B) to the supply air line ( 9 ), the other can be connected alternately to the line ( 18 ) leading via the heat exchanger ( 3 ) into the free atmosphere. 17. Plant according to claim 8, characterized, that at the from the fresh air inlet to the mixer piping leading the heat exchanger immediate bypass line is arranged.