DE3313987A1 - Building heating device - Google Patents

Abstract

The heat exchangers (13) in the building heating device according to the invention are equipped with glass pipes (3), the ends of which are internally flanged and have an extraordinarily high section modulus against impacts. Moreover, appliances (16-18) are provided which set off an alarm on glass breakage or leaking, or stop the heating. <IMAGE>

Description

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PATENT ADVERTISEMENT DIPL.-I NG. \ ZZ 'Z ll''ZZ. Z

HERBERT HAMMERMANN ⁸⁵⁰ ° ™ ™ * f ^G ' * ■ ¹⁵ · ^{April 19i}

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Rnf: 0911 / 593693mMl593388

Bank account: Dreidner Bank, Nuremberg Wire: Pathaunmer Nuremberg Deposit box Rathenatrplatz No. 2012510 Bankleltiabl 76080040 -s Bayer. Vereinsbank Nürnberg No. 5906393 Bankleitxahl 76020070 "O

Current account: Stadtsparkatse Nürnberg 1088193 Bank number 76050101 Postal checking account: Nuremberg Office 477 06-857

Klaus-Dieter Reininger, Burkhard Reininger, Klaus Andrick all resident

Otto-Bödecker-Strasse 16, 3160 Lehrte

Building heating device

description

The invention relates to a building heating device with neutralization and the exhaust gases falling below the dew point, with ion exchangers as well as with heat exchangers consisting of a plastic container with small groups of glass tubes exist for the passage of the exhaust gases.

The invention is based on the object of increasing the efficiency of the heating device even further, and for this purpose to ensure that the heating is switched off if the glass tubes break or one of the heating coils leaks.

The object is achieved according to the invention in that the small groups of glass tubes wn heating coils for the domestic water and space heating are surrounded and the free space of the heat exchanger with standing water is filled, the level of which is

run is regulated that in the event of a pipe break the heating is turned off and an alarm device is activated, and that then the exhaust gases flow through heat exchangers, which preheat fresh air drawn in by a fan for the heating system.

The drawing shows a building heating device according to the invention, for example and predominantly in the form of a sketch, and although shows:

1 shows a building heating device according to the invention in vertical cross section,

Fig. 2 shows a somewhat more compact design thereof in a horizontal section and

3 shows the end of a chimney in a building heating device according to the invention in longitudinal section.

4 shows the flanged end of a glass tube in a longitudinal section.

From a building heating system of a known type, the Exhaust gases through pipe 1 into a distribution space 2, flow through groups of glass tubes 3 and then arrive from a collecting space 4 from through an elastic connection 5 into a collecting space 6, then flow through glass tubes 7 down into a Collecting space 3 and finally pass through glass tubes 9 sucked in by a fan 10 into a plastic chimney 11 with further held sheath 12.

The glass tube 3, which are combined into groups of seven pieces and housed in a plastic container 13, are surrounded by pipe coils 14, 15, of which the pipe coil 14 for; the building heating, the pipe coil 15 for COPY

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serve to heat the domestic water. The glass tubes 3 are surrounded by standing water, and connected to a high-level container 16, which apart from a maximum switch 17 in the event of breakage of the pipe coils 14, 15 and a minimum switch 18 in the event of breakage of the glass tubes still has an outlet 19.

The glass tubes 7 and 9 are located in a container 20 with a partition wall 21 and are surrounded by fresh air, the is sucked in by a fan 22 and at 23 after the boiler of known design, not shown here, weitei is directed.

The containers 13 and 20 are arranged above a trough 24, the upper part of which is formed by a partition 25 into the distribution space 2 and the collecting space 8 and the lower part of which forms the neutralization liquid via a metering pump 26 gets fed metered from a neutralization tank 27. A metering pump 28 ensures that through Supply pipes not shown here baffles 29 to 32 the neutralizing liquid in sufficient quantities gen received. The neutralizing liquid abundantly supplied by the metering pump 28 passes to film-like Spread through the baffles 29 to 32 back into the tub 24 and can through return openings 33, 34 in the Return floor 3 5 to the lower Raujji de.r tub 35. If the amount of the neutralization liquid increases as a result of the accumulating condensate, it can no longer be used Liquid pass through the condensate overflow 36 into an ion exchanger 37 with cations 38 and / in ions 39

ORIGINAL INSPECTED COPY

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Which are separated from one another by a partition 40 which does not extend all the way to the floor. At 41 is a Outlet, which leads to the municipal sewage system. With 42 there is a pH control, with 43 one Level control for the condensate in the tray 24 is designated. A solenoid valve 44 is used to activate the fan with neutralization fluid only at the end of the heating process 10 to clean again.

The system according to Fig. 1 works as follows:

The exhaust gases from a heating system (not shown here) enter the pipe 1 made of glass or ceramic. There, at 29, the exhaust gases, which have a temperature of about 600 °, are heavily sprinkled with a neutralization liquid such as ... Caustic soda. This lowers the temperature of the exhaust gases so much that they touch the following plastic parts cannot cause destruction. Due to the strong cooling achieved, the dew point is undershot and a Reached a pH of around 2.4. The exhaust gases are thus even when SO- or SO_ are formed with the neutral sation agents mixed and chemically with the resulting Bound condensate. Combustion residues and pollutants are also bound in the condensate and are created no micro-deposits as would be the case with a subsequent neutralization of the exhaust gases.

After the sprinkling at 29, the exhaust gas flows through the glass tubes 3 of the two plastic exchangers 13 and enters the upper area 4 of the heat exchanger. The glass tubes 3 are heated by the exhaust gas and the heat is dissipated by the ■ standing water in the containers 13 on the metal coils

14, 15, which enclose the glass tubes 3 in the containers 13. The lower pipe coils 15 are used to preheat the domestic water, the upper pipe coils to return heating to the heater. Both systems are required to avoid overheating. If, for example, no domestic water is taken from ν, the heat is transferred to the coils, which are used to heat the return. In the upper area of the heat exchanger there is the expansion vessel 16 and the safety overflow 19 into the sewer system. In the event of a pipe burst, the expansion vessel fills and the maximum switch 17 gives an alarm and the heating system switches off. If a glass tube is destroyed, the heating system is switched off by the minimum switch 18 and there is an automatic switchover to the normal chimney. In the upper area there is again a sprinkler 30, which has the task of transferring the heat that was absorbed by 29 during the sprinkling to the glass tubes. It also serves to neutralize. The exhaust gases then reach the air heat exchanger 7 and are deflected into the lower region 8 by a partition 26 ′. There is again sprinkling at 31. The exhaust gases reach the second air heat exchanger 9, are sucked in by the fan 10 and pressed into the plastic chimney 11. Sicy is the sprinkler 44 to difent to clean the fan to the fan 10th This cleaning, however, only takes place after the burning time, while the fans are being turned on. The follow-up time is determined by a time relay in order to ventilate the system after the burning time.

ORIGINAL INSPECTED COPY

The speed of the blower is electronically adjustable to one A wind of 0.01 millibars can be achieved between the heat exchanger and the boiler. This is necessary because the there is still moisture in the chimney. Because the exhaust gas temperature If the temperature is only 22 ° C, plastic can also be used there without hesitation. The condensate that is in the Plastic chimney collects, gets through the existing drain back into the air heat exchanger.

In the plastic chimney, there is a fuel oil consumption of 1 per 1000 approx. 200 1 condensate, 1,500 1 condensate in the heat exchangers.

The two-stage air heat exchanger 7, 9 gets over a Fan 22 fresh air is supplied, which is sucked in from the outside and pressed into the air heat exchanger. This creates A slight overpressure in the air heat exchanger and all surfaces are cooled by the fresh air. Continues to arise this cooling also creates a considerable amount of condensate. The preheated fresh air reaches the heating room or over a pipe and a filter in the living quarters. The monitoring of the fresh air takes place via gas sensors to prevent that harmful gases penetrate living spaces. In the event of a fault, the system switches off and gives an alarm. All of the condensate the system passes through two return lines 33, 34, which are located in the floor 35, into the tub 24. Rotary connection of the condensate The tank with the heat exchanger consists only of the two returns. This will remove the surface of the condensate kept particularly small and no evaporation of the cohdeiisate can take place. Through a condensate overflow 36 the level is always kept constant. COPY

If a defect occurs, for example a 'Riii in' KonäenscitbeTiält
would, the electronic level monitoring 43 reports a malfunction and the system switches off. The condensate passes through the condensate overflow 36 into the cation exchanger; and then into the anion exchanger 39. The condensate is desalinated by the two exchangers and can be directed at 41 into the municipal sewage pipes. Another possibility is to pump the condensate into a storage tank and from there feed it into the toilet cistern. As a result, drinking water is saved and the sewage treatment works are not subjected to any higher loads as a result of the measures according to the present invention.

If a glass tube is destroyed, the plastic containers pulled out of the holder and replaced the defective tube.

In order to be sure to prevent damage to the new glass tube by a layperson, the ends of the glass tubes are with
with a radius of curvature of about 5 mm inwardly in the shape of a quarter circle. You thereby get according to the laws of
Strength theory about 1500 times the section modulus compared to a glass tube simply cut off at the ends and
are well protected against even very hard unintentional impacts. A glass tube designed in this way is shown approximately in FIG
shown natural size. It can easily be stuck through a rubber ring 45 in an annular groove 46 of a base plate 47 and is securely held by this rubber ring in the annular groove with every pressure in the. prescribed location!

The following are the essential points of a building heating system according to the invention in key words:

ORIGINAL INSPECTED

BAD ORIGINAL COPY

INCOMPLETE

Heavy sprinkling to reduce the temperature from about 600 ⁰ C to 200 ⁰ C.

Triple sprinkling with neutralization liquid. Fan sprinkling during after-running via a solenoid valve.

Binding of pollutants through sprinkling. Falling below the dew point.

Plastic chimney with drain -

Basic exhaust air possible.

Chimney head cladding for the purpose of chimney head cooling through circulation when exposed to sunlight.

Heat transfer from the glass tubes to the standing alkaline water with pH value 8 and to the metal coils.

Heat transfer from low pressure to high pressure.

One or two metal coils in a heat exchanger.

Multi-stage air heat exchanger.

Fresh air is pressed into the air heat exchanger.

Separating floor between condensate and exhaust gas flow in the lower area with two return openings prevents evaporation of the condensate.

Follow-up control of the fan via a time relay. Switch-on delay of the burner in order to receive an updraft beforehand.

Speed control of the exhaust fan in order to achieve a pressure difference of 0.01 millibars between the heat exchanger and the boiler obtain.

Condensate desalination through cation and anion exchangers.

With heat exchangers made of plastic and glass, no metal components can get into the wastewater.

BATH ORIGINAL

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1 pipe 43 Level control Coiled pipe for the domestic water 2 Distribution room 44 solenoid valve high overflow tank 3 Glass tube 4 5 rubber ring Maximum switch 4th Collection room 46 ring groove Minimum switch 5 elastic connection 47 base plate Overflow 6th
7th Collection room
Glass tube r radius of curvature container 8th Collection room Intermediate wall 9 Glass tube fan 10 fan Exit of warm fresh air 11th Plastic fireplace Tub 12th wide covering Neutralizing liquid 13th Plastic container Dosing pump 14th Coiled pipe for heating Neutralizing agent container 15th Dosing pump 16 up to 32 baffles 17th , 34 return opening 18th floor 19th Condensate overflow 20th Ion exchanger 21 Cations 22nd Anionone 23 partition wall 24 Overflow 25th pH control 26th 27 28 29 33 35 36 37 38 39 40 41 42

Claims (3)

PATENT Attorney DIPL.-ING. : Z ~. '' ~~ ~~~ - '2 ^ Z. _Z iirnnmT UA KA KA CD KA A MfCf 8500 NUREMBERG, April 15, 1 < HERBERT HAMMERMANN Call: 0911/592693 and 593388 Bank account: Dreidner Bank, Nttrnb «rg Wire: Pathammcr Nürnberg Depositenkasse Rathenauplatz No. 2012510 Bank code 760800 « Bayer. Association «bank Nürnberg Nr. 5906393 Bankleitzabl 76020070 Current account: StadtsparkaMe Nürnberg 1088193 Bankldtnummer 76050101 Pottschedckonto: Amt Nürnberg 47706-857 Klaus-Dieter Reininger, Burkhard Reininger, Klaus Andrick all-resident
Otto-Bödecker-Strasse 16, 3160 Lehrte Building heating device Claim Building heating system, with neutralization and the dew point of the exhaust gases, with ion exchangers and with Heat exchangers made from a plastic container with consist of small groups of glass tubes for the passage of the exhaust gases, characterized, that the small groups of glass tubes (3) from heating coils for domestic water (15) and room heating (14) v. are given and the free space of the heat exchanger is filled with standing water (16), the level of which is through a safety outlet (17) is regulated so that in the event of a pipe break the heating is switched off and an alarm device (18! is actuated, and that then (5) the exhaust gases Wärmeaui ORIGINAL INSPECTED BAD ORIGINAL Exchanger (20) flow through, which by a fan /; (22) Preheat the fresh air drawn in for the heating system. 2. Building heating device according to claim 1, characterized, that the glass tubes are uragebördelt at the ends inwards. 3. Building heating device hach claim 2, characterized in that the flanging at the ends of the glass tubes forms a quarter of a circle with a radius of curvature of approximately r = 5 mm. BAD ORIGINAL COPY