DE1551994A1 - Heat pump for heating and hot water preparation - Google Patents

Description

Heat pump type for heating and for hot water heat pumps The bi4jetzt become known after the compression principle of electricity as an energy source aus.Der high electricity price prevents fIeizzwecken to its' general application.

Heat pumps based on the absorption principle can work with cheaper primary energy (coal, oil, gas) or Waste energy (exhaust gas, exhaust steam, waste water) can be operated, but unfortunately there is still not an ideal pair of substances that is both non-toxic and corrosion-wise satisfactory.

The invention describes a gas- or oil-operated compression heat pump in order to reduce the costs of building heating and hot water preparation.

This happens quietly in the following way: The oil shown in Fig.1 or GasmotoxA burns the heating oil or Gaa and drives a compressor (K).

One of the usual working fluids (preferably Frigen 12 or 22) is liquefied in the condenser (Ko), is expanded in the expansion valve () and evaporates at Outside temperature (Ta) in the evaporator (Ve). The heat generated in the condensate (Ko) and supply the waste heat from the oil or Gaamotor (bi). the entire heating.

The amount of heat that the evaporator (V9) withdraws from the atmosphere corresponds to the saving of fuel.

The waste heat from the engine (Ii), cooling water and through heat exchangers (W) The exhaust heat extracted falls between 70 and 48 degrees, so it can be used directly in the 1st refrigerant circuit (water) through radiators (üKI) to the room to be heated hand over.

When capacitor (Co) is Schwierigkeiten.Man result may consist SicherheitagrUnjen not use directly as a radiator (high pressure of Frigens, Geruehlosigkeit over at Lndichtigkeiten _ a Zera®tzbarkeit of open flames to toxic components) Therefore, in the 2.äeizmittelkreislauf (water condenser ) the heat is taken over by the condenser and transferred to the radiator or radiators (HK2).

. (HK2), however, must have a significantly lower flow temperature alg (HK1). Because according to Carnot the performance figure of the Heat pump process otherwise it becomes too low.

A low radiator temperature (30 to 50 degrees) of (:; h2) leads but too unacceptable large curses that are neither in the normal building architecturally are to be accommodated, can still be armored.

The solution is based on two cradles a.) The entire outer walls, the lowest floor and the uppermost ceiling of the building to be heated receive in the plaster, or. Hodentelag a dense network (N in Fig.2) of hoses, tubes or Lohlen plates through which the heating means of the 2.fieizmittelkreislaufes pumped wird.Die temperature of the wall boundary layer to thereby obtain na hezu room temperature.

if desired, the window between double panes are connected to the 2.üeizmittelkreislauf, the transmission heat losses of the building could be covered via the capacitor circuit as. (HK1) then must apply to the transmission loss ventilation heat requirement and under normal windows and doors.

(P) in the figures means heating fluid pumps. quantitatively results With this version the following results: The ventilation heat requirement is normally between 1; and 30% of the total heat requirement. Iiei surcharge for windows and doors it should be 40 to 45% over (FIK1) and the other 55 to e0; o over (MR2) so walls, deeke, floor to be delivered.

At minus 20 degrees outside temperature, minus 30 degrees evaporator temperature and around plus 30 degrees condenser temperature, the heat pump circuit with Frigen 12 as the working medium has a performance figure of 3.57 with a quality level of the compressor of 0.8.

The oil or gas engine (M) has a low level of efficiency of 23%. After transmission losses, he still gives 21.7% of the oil or gas energy the compressor shaft.

Then 3.57 to 21.7 - 76.6% are available in the capacitor. from The 77'f waste heat is completely lost 15% in the exhaust to the exhaust gases a reasonable To give buoyancy and not to fall below the dew point (corrosion). Stay 5o for (HK1) 77 - 15 = 62% obtained.

The total heating is therefore 76.6, +62 -138.6 f. If one draws the total number of arms down to the full iic: value of the e; pure substance, this results in a ljrsF, arnis of 28 rö. vt-: r if one equals the total heating energy. but with a normal one izeizcng, which yes, at least 1 5; @ has increased exhaust gas loss.-_ i the r: iz`k.! iC @ Ie considerable savings. This I: ei.i`i@etrag is intended to be used in part for the heating medium pumps and possibly n; itit; e fan on the evaporator or on the Miser as consumed B = elten. Pumps and fans are driven directly by the I: otor (. :). If this is not possible, use an evaporator on the brook of the cia:; ses or in the case of several fan coils or the further - : Änte.n labeled blower radiators, then the motor generates (m) up to about 10; ü its output electric current to the dilfsaggregate to drive. I) fp & er loss is always already in the following calculations deducted. Since the outside temperature is seldom long at minus 20 degrees remains, i;: t the average savings to be achieved over the Stimulus period naturally greater than 28 °; l). The following `table shows how the fuel savings developed at different outside temperatures., 'The vaporizer is always ten degrees colder than the outside air, the capacitor has 30 degrees. The performance figures are derived from the usual working diagrams for politrophic compression. Outside temperature coefficient of performance i :: echanical condenser Energy in performance: (Tq t Komprez: @. Orwelle ex 2197 @ _20 gra d- 3- e57 21., 7 f 7696 -1o 434, @ 94; ö 0 1 21 3 .r p + 737 @, 168 +20 1-194 @i 248- Y Total heat output in savings, if the usable waste heat (62 lö) + t..ntere @ieizwert des 1; ondensator power = rennatoffes = 100 5.1 (Ta) -20 degrees 13896% 28 5ö -10 156 36 `0 183 y @ 46% +10 210 j 56 774 +20 310; @ 67, 7Y3 Ratio of usable waste heat and condenser line at the different outside temperatures:. (Ta) usable dropout capacitor power -20 degrees 446 i '' - 55 9 4 5G -10 3997% 60, 3 0 34 i 66 + 1o 27 Jn 73 +20 20; Q 80 Assuming an average outside temperature of between 5 degrees and approx. F degrees during the stimulation period, an average fuel saving of 40 to 50 can be achieved. These high savings justify the use of the machine units instead of the usual boiler, even if the engine and compressor need to be overhauled after about 5 years. The last table shows the relationship between usable waste heat and condenser output. This ratio is very important because if the usable waste heat is lower than the ventilation heat demand,. should the temperature of the neizsohläuehe (N) increased above itaumtemperatur the percentage of waste heat nutzbareh werden.Liegt above the ventilation heat requirement, the temperature of the Xeizschläuche (N) and thus the capacitor can be lowered.

Since this F, 11 occurs at low outside temperatures, where the main heat consumption is, the coefficient of performance of the heat pump process increases and thus the Savings.

The poorer performance figure due to the increased wall temperature of the network (N) , on the other hand, is not so significant. In normal buildings , an increase in the wall temperature from +10 degrees outside temperature by a few degrees should be necessary , on the other hand, the required condenser and wall temperature decrease by at least ten degrees at (Ta) -20.

Is to be heated übäudea of ventilation and Fenstortransmissionaverlust from the start too high or are the water-bearing exterior walls cnerwünsQht, so this solution can not be applied by the .Bauart.

b.) The second solution to the problem, without being forced to penetrate all external surfaces with hoses or pipes, is shown in Fig. 3.

A fan heater (GHK) of a special type, described below, emits the neizwärme to the room .

The heating medium is heated up on the condenser (Ko) from 25 to about 35 degrees, passed through the oil or gas engine and the waste heat is heated to about 42-45 degrees (at Ta-20 degrees).

The fan heater is built in such a way that, despite the low, average heating medium temperature of only about 35 degrees, it does not assume huge dimensions. The poor heat transfer coefficient from radiators z # g f to air 1A SST through the increase of the relative Geschwiniigkeit increase between air and metal. If a normal fan coil is used, this can rtela tive speed low noise up to approx. 8 m / sec The k coefficient (heat transfer coefficient is dan + a. 2 + 108 -approx. 30 Koal / h nt "degrees. After all, this is four times as much as one Normal radiator or convector. But it is the high energy expenditure for the unnecessary acceleration of the Air hardly bearable. It would noticeably increase the performance figure of the entire process deteriorate. Dept.-4 and 5 each show a solution: To fig. 4: A motor-driven, hollow fan blade is used in the Inside of the irritant flowed, flow and return the hollow axle with mechanical seals was allowed to go. In the large, thin, stroalin-shaped fan blade guide bars are arranged, which the heating medium in countercurrent The angle of the fan blade to the plane of rotation is so low that at the highest possible circumferential speed, only the amount of air that is required for transport is conveyed the necessary amount of heat is sufficient. Because of the noise, the limit of the speed at about 20 a / sec. This results in # eia k value of approx. 2 + 10 f2 "0. approx. 46 Kcal / h J degrees. So one eighth of the heating surface of normal radiators or in the case of the heat pump with a low heating medium temperature about half. Since the air output per 1000 keal / h is only about 250 m / h for some Millimeters of total pressure achieved @ is the energy requirement a seblaoe radiator built in this way despite the high k-number. .minimum and remains below 10 # 4 of the Ibtor power of the notor (M). h @ .c, I = e @ .sti.uisziffc = r this i @ nordnüng is less than with solution a.) with your wall network (N) since the condenser temperature hardly under three3; ie; Press degree lä. :: t. To Fig.js add more h'si.ng of @ieizl: spexprolslems, d @ sc? a; decEiaerde in the case of a wlärmept "impe, it is possible to use even less energy a:., t'wand dadi: roli achieve that one or more hollow, heating medium Rotate through-flow discs at high speed. (::, more than 20 mI's possible) The disc or discs are,. streamlined; = organized and the Sciiaci: t »cs, as well as the itadial acceleration of air near the disk particles take care of the promotion of the exhaust air. A third variation would be to keep two heating circuits and the use of the @ blower or The 1st heating element circuit with the high The flow temperature could be via normal aadiators or convectors heat, the c. via the fan radiators. However, this solution results in the most mirixinal heating surface requirement awkward strand guide, 2 pumps, etc. The control of the (il or gas engine, the expansion valve, the nimping and ventilating are carried out with the known devices and circuits. : with an automatic defrosting device for the evaporator, a Electric starter on the gas or oil engine can be used Achieve the same ease of use as with the usual heaters. Good soundproofing of the in-machine room is natural necessary. The installation of a; Va rniwaaserbmilers or water heater into the waste heat cycle or with temporarily increased condensation satortemperat "r ° Z @: H. in summer) in the condenser circuit does not cause any problems. The fans or panel heaters are also suitable independently from the heat pump to installation in conventional heating systems. At a high flow temperature, the dimensions would be very small result, which disturb the architecture less than the biynow - built-in: The advance of the invention over the known heat pump systems is that the currently cheapest primary energy from ß1 or gas can be used for a compression heat pump.

The provided discs or fan heating elements allow a economical mode of operation with low capacitor. temperature, which is at Execution with the wall net lowers even more.

A savings in license costs of 40> over the heating period the even greater savings in water preparation result in quick amortization the plant.

mention. there is also the elimination of the chimney in new buildings and the replacement by a much thinner exhaust pipe If in the next ten or twenty years the electric: itrom from atomic energy would become cheaper than heating oil or gas, the internal combustion engine could be replaced by an electric motor.

The system then has lower heating costs than with direct electric heating.

However, the possible conversion must be planned. (Larger or second compressor, only fan heater) The Eiffindung is also particularly suitable for the supply of large amounts of water for indoor swimming pools, scriwimmi licks etc. Since the same problems arise on the evaporator as on the heat exchangers (low temperature difference, it is also expediently built like the blower or disk heater .notfalla,.. With the interposition of a heat exchanger if necessary Frigen A cooling medium circuit would then be switched on between the evaporator and the discs or fan cooler9.

If a lake or a river is nearby, the evaporator is brought into it under all the sewage flowing out of the house, which is mostly warmer than the outside air in winter 1 could also be used and cooled down to approx. +2 degrees, a higher performance figure would be the result.

If the evaporator is located in a body of water, it must of course be possible to switch to an evaporator in the air for the days when the air is warmer.

Claims (1)

'Patent claims r, 1st heat pump for heating and hot water preparation thereby. characterized in that an oil or gas engine drives a compressor, the working medium circuit of which extracts heat from the environment, which is used together with the usable waste heat of the oil or gas engine . 2. Heat pump according to claim 1, characterized in that the amount of heat occurring at the condenser of the working medium circuit is released through a tight pipe or hose network in the outer surfaces of the building to be heated just below the inside (interior plaster, floor), so that if it is heated, double! Windows as much as possible of the franmissions heat loss is covered. 3. Heat pump according to .Anspruch 1, characterized in that the usable waste heat of the oil or gas engine with a high flow temperature covers the ventilation heat requirement and reads the transmission loss. 4. Heat pump according to claim 1, characterized in that the temperature of the condenser und'damit the wall network is above or below room temperature, depending on the different heat distribution between the condenser and waste heat at the different outside temperatures. 5 heat pump according to claim 1 characterized in that the amount of heat from the condenser and the waste heat from the motor are released to the rooms to be heated together or separately via fan heaters, the hollow fan blades of which are flowed through by the heating medium. 6. Heat pump according to claim 1, characterized in that the 'hollow fan blades de # - Gebläseheizkörperji at the highest possible circumferential speed delivers the smallest amount of air required at the lowest total pressure: 7. Heat pump according to claim 1 characterized in that hollow Discs rotate and a shaft above them as well as the radial acceleration of air particles near the disc provide the air transport. 8.W'd.rmepumpe according to claim 1 characterized in that the evaporator has the same type of construction as the fan or disk heater. 9. Heat pump according to claim 1, characterized in that the auxiliary energy for pumps, fans, evaporators is generated by the till or gas engine. 10. Heat pump according to claim 1, characterized in that the system is set up so that with cheap electrical energy costs, a conversion or conversion is also possible retrospectively.