DD153726A1 - METHOD AND ARRANGEMENT FOR BACKUP COOLING IN REMOTE WATER SUPPLY SYSTEMS - Google Patents

Abstract

The invention relates to a method for Rückllaufauskuehlung and thus to expand the Netzkapazitaet existing or newly created Fernwaermesysteme by using the return heat decentralized transfer points (customer systems) using absorption heat pumps and an arrangement for carrying out the method. Its aim is to enable the connection of a larger number of heat consumers with conventional space heating systems and domestic hot water supply to existing or new district heating systems with the least possible outlay on electrical energy and control equipment. The object of the invention is to realize the running in an absorption heat pump processes by the Primaervorlauf a conventional district heat supply system and Auskuehlung its return, while generating useful heat according to the conventional secondary flow parameters. It is essentially solved by both desorption and absorption in several stages at different pressure and temperature levels in a single cycle.

Description

218

a) Title of the invention

Method and arrangement for return cooling in district heating supply systems

b) Field of application of the invention

The invention relates to a method for Rücklaufkühlkühlung and thus to increase the network capacity of existing or newly to be applied Fernwärmesysterne by using the return heat decentralized transfer points (customer equipment) using absorption heat pumps, and an arrangement for carrying out the method,

C) characteristic of the known technical solutions

As the capacity of a district heating system - i. the total available for space heating and domestic hot water preparation of customers heat output - from the difference between flow and return temperature and the Massenstr-om, the realization of low return temperatures is of great importance for the rational operation and the effectiveness of large district heating systems. For the Y / eitere utilization of the heat content of heating water from the district heating return for heating and domestic hot water preparation solutions have been known so far, which can be assigned to two fundamentally different physical principles:

- The return water of conventional heating systems is by specific wiring and / or directly connected to the return low-temperature heating with accordingly

However, this requires eg for the transition from the heating network parameters 90 / 7O ⁰ C to 60/40 ⁰ G, an increase of the heating surfaces by 200 %, is therefore associated with high investment costs.

The temperature level of the return water of the secondary circuit is raised to the conventional heating system by means of suitable heat transformation units, whereby the primary return is further cooled.

According to principle 2, the use of heat pumps whose mode of action is based on the transformation of heat from a low temperature level to a higher one is pur solutions. Based on its more favorable performance index (emitted energy: drive energy = 3), almost exclusively compression heat pumps are used, but their operation requires a high expenditure of electrical energy * All components of a compression heat pump must also exceptionally high-quality material to withstand the high pressures of the working media used. In contrast, absorption heat pumps have only a low power requirement for electrical energy, which is only required here for operating the solvent pumps. The heat pump process itself is based on the effect of a two-component mixture to heat out a component (heat) and absorb it at a higher temperature level, so it can be started by a suitable, available heat source. Compared to the compression heat pump, however, a conventional absorption heat pump only has a power rating of about 1.5; It therefore requires for the transformation of the return temperature of a district heating system (70 C) to the secondary flow parameters of a conventional heating system (90 - 110 ⁰ C) Austreibertemperaturen, which would be far above the temperature of the primary flow (150 C) .- as available heat source »

Although various solutions have already been known, by clever circuit variants, the thermal energy drive better than previously possible, to use for the release of heat and thus increase the potential uses of absorption heat pumps. However, these solutions relate only to a more favorable flow of the internal heat pump process by the involvement of compressors or heat exchangers, without changing the fundamental structure (expeller condenser - evaporator - absorber) of the absorption heat pump and above all, without achieving a significant improvement in the codes , Thus, according to the known circuit arrangements, the heat given off by an absorber heat pump heated by the flow of a district heating pipe can only be used for the brewing water heating or low temperature heating systems of the users *

The aim of the temperature range between the heat to be used and heat heat to be extracted larger, and to be able to make variable in both ^ directions, served the development of the known absorption heat pump * This basically also works on the principle of absorption, but has two separate, parallel solvent circuits, the Capacitor is replaced by an absorber and the evaporator by a second expeller »The resorption process requires fixed at operating, a conventional space heating suitable heating temperature even expelling temperatures that are higher than the usual temperatures of a district heating primary flow (about 150 C) and In addition, control technology is very difficult to control, since in both circuits always the same amount of steam must flow of the same concentration, or, a defined solvent compensation must be realized to the Wärmep umpenprozeß not to come to a standstill.

d) Object of the invention

The aim of the invention is to increase the capacity of existing or new district heating supply systems by making better use of the heat output provided by the HW / HKW with the least possible outlay on electrical energy and control equipment and thus connecting a larger number of heat consumers with conventional space heating systems and domestic hot water supply * At the same time, the construction and investment costs for the construction of new HKW / HW locations and the associated environmental impact should be reduced «

e) Presentation of the essence of the invention

The object of the invention is therefore to develop a method and a corresponding arrangement to the running in an absorption heat pump "desorption" (recording of low heat high temperature) and "absorption" (release of much thermal heat medium temperature) by the Primary flow of a conventional district heating supply system and cooling of its return, while simultaneously generating heat recovery according to the conventional secondary flow parameters «

This object is achieved in that both desorption and absorption in several stages on each different pressure and temperature level in a single cycle in which the rich solution is gradually or - by dividing the mass flows - parallel, deh · simultaneously depleted, wherein a portion of the coming from the customer systems return (about 70 C) for the expulsion of the more volatile component of the binary mixture and then or * simultaneously energy of the primary flow (ca * 150 C) used for the complete degassing, ie "depletion ^{11 of} the solution The re-enrichment of the depleted solution (absorption) then takes place just as well

Gradually to each selectable pressure and temperature level with heat transfer to the secondary return · This heats the secondary return (about 7O ⁰ C) again to the required secondary flow temperature (approx., 90 - 110 ⁰ C) and fed back into the Abnehme ranlagen, while the primary return a cooling down to ambient temperature (about 20 ⁰ C) erfährto

In accordance with the invention, instead of the condenser, one or more absorbers are used in series and / or in parallel with one another and / or several further expellers (degasifiers) and temperature and pressure regulating devices serving to optimize the internal process Temperature Changer, Reducing or ₀ Throttling Valves, Compressors - arranged in a single, step-wise adjustable absorption heat pump circuit located between the primary and secondary circuits of a conventional pernicious supply system (transfer station) »

The advantages of the invention lie in a considerable saving in electrical energy compared to comparable solutions with compression heat pumps, in overcoming the control problems in circuits with absorption heat pumps and in the possibility for considerable investment savings through the expansion of the capacity of existing Pernwärmenetze

f) embodiment

The invention will be illustrated below with reference to three exemplary embodiments of a customer system with conventional parameters and the substance combination ammonia / water. In the accompanying drawing:

Pig «1 with a circuit arrangement according to the invention

gradual absorption and desorption, according to Example 1

4 ft. Ft

Figo 2 a circuit arrangement according to the invention with gradual absorption and run parallel to the desorption, according to Example 2

a circuit arrangement according to Example 3

another Hilfsaustreiber and three-stage absorption

1 "Fig. 1 shows a direct feed intake system for a customer with space heating and domestic hot water demand based on a gradual desorption and desorption. The Heizv / asser enters with about 150 C from the primary network 1 in the expeller 3 · ^/ 1 and passes after a heat release with the desired secondary flow temperature of 90 C in the space heating systems 10 of the heat consumer »Thereafter, the return water from the space heating systems to Nutzswarmwasser bereititer 9 led. Prior to this, a portion of the return water for reheating to 90 ⁰ C in the absorber 4.1 and 4.2 is averse, while leaving the use of water heater 9 return water heated degasser 3 * 2 and enters with about 20 C in the return 2 of Primärnetzea 1. The actual heat pump process is as follows: The "rich solution" of the binary system enters the degasifier 3 · 2 from the absorber 4.1. "In order to achieve a high degassing performance, a heat exchange with the" poorer solution "takes place in the heat exchanger 5. , By throttling in the valve 7 · 1 and by supplying heat from the return 8, the degasser 3 · 2 carries out an expulsion of the more volatile component as steam, which is conducted into the absorber 4.1. The poorer solution is then conveyed by means of the pump 6 * 1 in the expeller 3 · 1, with a heat exchange with the further depleted solution in the heat exchanger 5 * 2 is made. In the expeller 3 · 1, the heating water of the primary flow 1 now causes the further desorption · The steam released thereby flows into the water

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Absorber.4.2 and the poor solution after throttling in the valve 7 · 2 in the absorber 4.1, where it absorbs the heat of low pressure to the secondary return water. The resulting richer solution is promoted by the pump 6 _e 2 in the absorber 4 _O 2, v / o they absorb the high pressure steam, also with heat to the secondary return 8, The heat exchanger 5.2 is used to increase the absorption temperature, the compressor 11th increasing the pressure between degasser 3.2 and absorber 4 _e 1.

2, the principle of the stepwise absorption is retained, but the desorption takes place in parallel. For reasons of clarity, the heating circuit and the intermediate heat exchangers have been omitted. Their classification is in accordance with Fig. 1. After the absorber 4.2, the rich solution after compression by the pump 6 or throttling in the valve 7 according to the services on expeller 3 «1 Ufld degasser 3«> 2 split. There, the desorption takes place from the supply and return by heat. While the poor solution from the expeller 3 <> 1 after throttling in the valve 7 absorbs the vapor from the degasser 3 «2 in the absorber 4.1 and thereby heats a portion of the return water to the desired flow temperature, the steam is higher pressure through the poor Solution of degasser 3 · 2 and the enriched solution from the absorber 4.2 after compression in the pump 6 absorbed in the absorber 4.1

3 * Is already a relatively low return temperature, e.g. By use of domestic hot water, available, so a further reduction by a Hilfsaustreiber 3 »3 is possible, which is generally necessary only in the range of high secondary flow temperatures * The number of devices increases only seemingly, as in the achievement of the desired benefits in general always several Equipment are necessary, except that here they are based on three

retired union pressure levels work · The course of the process goes like this "from equip: The rich solution to the absorber 4.3 in the degasser 3 x 2" then depleted in pump _v 6 compresses and Hauptaustreiber 3 X 1 "at maximum pressure so far desorbed Following this, the "depleted" solution in valve 7 is throttled to an intermediate pressure and further desorbed in the auxiliary discharger 3 × 3 " The further course of the process corresponds to example 1"

Claims (1)

invention claim 1, ^ experience to Bücklaufkühlungung in Fernwärmenersorgungssysteinen by using the Rücklaufwärme decentralized Üb he present provide with the help of absorption Wämepumpen, characterized in that both desorption and absorption occur on each different pressure and Tem peraturniveau in a single heat pump cycle, with energy from the Customer systems (10) coming return (2) for the expulsion of the more volatile component of the binary mixture and then or, simultaneously energy of the primary flow (1) for the complete degassing, ie "depletion" of the solution are used and then the re-enrichment of the depleted solution ( Absorption) is carried out in stages, heating the secondary return (8) to the parameters of the secondary flow. Method according to item 1, characterized in that the rich solution is depleted simultaneously or in parallel, by differentiated distribution of the mass flows and at different pressure levels, while the enrichment of the poor solution takes place in several, successive stages on respectively different ones Pressure and temperature level is done, » 3 »arrangement for carrying out the method according to item 2, characterized in that instead of the condenser in series one or more absorbers (4) and instead of the evaporator in series and / or parallel to each other one or more further expeller / degasser (3 ) and for optimizing the internal process temperature and pressure regulating means (5 »7; 11) are arranged in a uniform, step-wise adjustable absorption heat pump circuit, the between the primary and secondary circuits of a conventional district heating supply system. 4 ", arrangement * according to item 3s characterized in that the degasser (expeller) (3) for power control and process improvement in each case with temperature changers (5) are coupled» 5 * Arrangement according to point 3 ^{un (} l 4, characterized in that the distribution of the mass flows of the absorber (4) leaving rich solution on die.Entgaser (expeller) (3) via throttle valves (7) « 6 "arrangement according to items 3 to 5", characterized in that in front of the stepwise arranged absorbers (4) each compressor (11) are inserted _o 7 © Arrangement according to items 3 to 6, characterized in that the degasser (3 · 1) with energy from the return and the or the expeller (3 · 2 and.3.3) are heated with energy from the primary flow (1). Hchnunqen