DD286038A5 - HEATING BOILER CALIBRATED WITH HEAVY EARS - Google Patents

Abstract

The invention relates to a boiler equipped with heat pipes, which is suitable in addition to the preparation of service water for low temperature heating systems. The boiler consists of an exhaust gas heat exchanger with built-in, the heat pipe receiving, labyrinthfoermigen plate heat exchanger, which has a central exhaust gas inlet and peripheral exhaust outlet and a spaced above it, equipped with the same continuous heat pipes Waermetraeger - heat exchanger. The latter is formed by horizontal, provided with openings O separating openings as provided with different temperature heating zones layered storage. In certain areas, the heat pipes are surrounded by insulating or heat-conducting material. The boiler is advantageously still provided with a heat pump cycle. The Heizkesel has due to the heat sorting and the associated utilization of the heat energy of the exhaust gases an extremely high efficiency. Fig. 1 {boiler; Waermerohre; Water; Low temperature heating systems; Abgaswaermetauscher; labyrinth-shaped plate heat exchanger; Heat carriers - heat exchangers; Layer memory; heating zones; Heat pumps cycle}

Description

For this 3 pages drawings

Field of application of the invention

The invention relates to a equipped with Wlrmerohren boiler, which is heated with Ges, oil or exhaust air, and in addition to the preparation of service water is also suitable for low-temperature heating systems.

Characteristic of the known state of the art

In the known boilers with heat pipes, which are characterized in comparison with conventional boilers by low downtime losses, the exhaust gases flow around the heat pipes and give their heat to this. The working fluid in the heat pipes evaporates. Since now the other end of the heat pipes is lapped by the colder heat transfer medium (ζ, Heiz., Heating water), condensation of the vapor, which releases its heat, which had been transported until then, to the heat transfer medium (DE-OS No. 322 8944). The disadvantage of these boilers, that the small flow rate of the exhaust gases around the heat pipe also leads to a low heat exchange. However, to achieve the required heat transfer performance, the boilers must be planted with a variety of heat pipes. However, the increased use of heat pipes is also caused by the fact that the flow around the heat pipes with the exhaust gases for each heat pipe is not optimally predetermined, so that not all heat pipes reach the maximum heat transfer. The mentioned flow around the heat pipes by the exhaust gases causes their premature corrosion and thus after a relatively short period of operation whose Ausfell, so that the functionality of the boiler is only partially or not guaranteed .. Another disadvantage of the boiler is still relatively unfavorable efficiency, as the Heat energy of the exhaust gases is not effectively exploited, especially when exhaust gases with low temperatures, eg., Exhaust air present.

Object of the invention

The aim of the invention is to develop a high efficiency boiler with heat pipes, the boi reduced material usage and manufacturing costs increased reliability and duration allows.

Explanation of the essence of the invention The object here is to avoid any direct contact of the exhaust gases with the heat in each heat pipe

Include an offensive heat sorting by temperature even in the presence of an exhaust gas temperature below the heat carrier temperature.

According to the invention, the boiler is composed of an exhaust gas heat exchanger and a distance above it Heat transfer heat exchanger together. The exhaust gas heat exchanger consists of a built-in a housing labyrinth plate heat exchanger, the Takes up the pipes. The heating surface of the plate heat exchanger encloses every single heat pipe, leaving one here Interspace in which thermally conductive powder is introduced. The exhaust gas heat exchanger has a central pipe for the Exhaust inlet. This tube has unidirectional openings or an opening in the form of a slot. Laterally in the Housing is the opening for the exhaust gas outlet. Below the plate heat exchanger is a condensate with twine Siphon for the drainage of condensate. The heat transfer heat exchanger is designed as a layer storage. In one housing are several, at a distance

stacked horizontal dividing plates, so that several heating zones arise. These heating zones are for the

Treatment of service water and the upper heating zone can usefully as a heat exchanger for a Low-temperature heating or used as a return preheater. The heat carrier inlets and outlets are peripherally mounted in the housing. Diagonally to each other have the dividers for the Service water heating zones a flow opening. The heat pipes located in the exhaust gas heat exchanger extend

simultaneously with Ober the entire height of the heat transfer heat exchanger, so that the arrangement of the heat pipes in

Heat exchanger heat exchanger corresponding in the exhaust gas heat exchanger. In the free area between the exhaust gas heat exchanger and Heat transfer heat exchangers are the heat pipes, which are gravitational heat pipes, isolated and indeed

expediently in that they are sheathed by a tube with space in which non-heat-conducting

Powder is filled. The heat pipes in the heat transfer heat exchanger are sheathed by a tube and here is in the gap

introduced thermally conductive and insulating powder and indeed the latter only up to the level of the corresponding tempering

Heating zone. As the temperature of the service water in the heating zones decreases from top to bottom, the insulation is from the inside

graded outwardly with the exhaust path decreasing. The outer heat pipes thus have no insulation, and also in the

The upper heating zones are not insulated. When operating the boiler, the exhaust gases rise in the central tube and

from there into the labyrinth-shaped plate heat exchanger. The exhaust fumes now flow from the inside to the outside and give their

Heat energy to the working fluid in the heat pipes from. The inner heat pipes are doing this with more heat energy

acted as the outer heat pipes. In the heat pipes upwards a complete heat transfer, as the

Heat pipes are isolated in the region of their transport zone. In the area of the condensation zone of the heat pipes, the one

corresponding heating zone is assigned in the heat transfer medium heat exchanger, the heat energy release, which leads to a gradual temperature control of the process water in the individual heating zones. At the same time, the upper, as

Heizungsvorwärmer serving heating zone with taken into account. To further exploit the heat energy of the exhaust gases, the boiler is equipped with a heat pump circuit. On the exhaust gas heat exchanger is now an evaporator, coming from the exhaust gas heat exchanger Heat pipes is stocked. A condenser is attached to the bottom of the heat transfer heat exchanger and needle-shaped Condenser tubes are in operative connection with the heat transfer medium heat exchanger. These needle-shaped condenser tubes

are up to the corresponding heating zone, as previously described isolated. Between the evaporator and the condenser is the

Compressor including relief valve switched. Its highly efficient boilers not only allow the treatment of process water, but he can

at the same time also be used for low temperature heating systems.

AusfOhrungsbelsplel The invention will be explained in more detail using an exemplary embodiment. The accompanying drawings show in 1: schematic representation of the boiler, 2: plan view of the exhaust gas heat exchanger, 3: section of the heat pipe, Fig. 4: schematic representation of the boiler with heat pumps - Kroislauf.

The boiler consists of the exhaust gas heat exchanger 1 and the distance above arranged heat transfer heat exchanger 2. Both heat exchangers 1,2 are equipped with the same continuous heat pipes 3, so that the arrangement of the heat pipes 3 in both heat exchangers 1,2 is the same.

The exhaust gas heat exchanger 1 has a closed housing 4a with a central exhaust gas inlet 5 in the form of a unilaterally slotted tube and peripheral exhaust gas outlet 6, in which a labyrinth-shaped plate heat exchanger 7, which is the Sekundärheizfläche, is installed. The plate heat exchanger 7 is made of unalloyed steel in the absence of an exhaust gas condensation and in the presence of an exhaust gas condensation of alloyed steel or enameled steel sheet. In the latter case, the exhaust gas heat exchanger 1 is still provided with a Kondensatwanno 8 with siphon. The secondary heating surface encloses the heat pipes 3 made of copper while maintaining an intermediate space. In this space thermally conductive powder 9a is filled in the form of iron powder.

The part of the heat pipes 3 between the exhaust gas heat exchanger 1 and heat transfer heat exchanger 2, which also forms the transport zone of the heat pipes 3, is insulated, so that almost no heat losses occur in this free area. The Wärmeträgsr heat exchanger 2 also has a closed housing 4 b, in which the coming of the exhaust gas heat exchanger 1 heat pipes 3 are housed. By spaced apart horizontally separating plates 10, the interior of the heat transfer heat exchanger 2 is divided into n.enrere heating zones HV, where *. 8. serve the heating zones NII for dhw heating and the upper heating zone IVz to operate the space heating, preferably underfloor heating is used. The heat carrier inlet and outlet, ie a service water inlet and outlet and an Eirtritt 'for the heating return and an outlet for the heating flow, are peripherally mounted in the housing 4 b. Likewise, the partition plates 10 in the heating zones MII for the service water have diagonally zueinderliegende flow openings. The heat pipes 3 Within the heat exchanger heat exchanger 2 are sheathed by a further larger pipe. The between heat pipe 3 and pipe awarding space is filled with powder and that to the effective range with insulating powder 9b, z. B. glass powder and then with thermally conductive powder 9a, z. B. iron powder. The heat pipes 3 are graded from the inside to the outside and associated with the exhaust path to the heating zones III, II and I, so that the insulation of the heat pipes 3 by means of the insulating powder 9 b is stepped from inside to outside.

During operation of the boiler, the exhaust gases pass through the exhaust inlet 5 in ds <center of the exhaust gas heat exchanger 1 a. With a flow velocity of -5 m / s, the exhaust gases are passed from the inside to the outside through the labyrinth-shaped plate heat exchanger 7. There they give off most of their heat energy to the secondary heating surface. The thermal energy to the evaporator of the heat pipes 3 passes through the thermally conductive powder 9a. The continuous evaporation and condensation process in the heat pipes 3 effects the transport of the heat energy from the exhaust gas heat exchanger 1 via the transport zone into the heat transfer medium heat exchanger. Eventue'l accumulating condensate from the exhaust gas is discharged via the Kondonsatwanne 8 with siphon. The order of the heat pipes 3 in conjunction with the labyrinthine design of the plate heat exchanger 7 leads to a graded operating temperature of the heat pipes 3 in dependence on the exhaust gas temperature. The transferred to the heat pipes 3 and sorted by heat heat energy is sorted radially and surface radially sorted in the heat transfer heat exchanger 2 to the heat transfer in the heating zones MV. So z. B. heated hot water at a temperature of 10 ° C to 60 ⁰ C. This multiple sorting of heat energy causes the hot water of the heating zone I, the exhaust gases without auxiliary energy to + 20 ° C cools, between the evaporator and the condenser of the heat pipes 3 is still a sufficient Temperaturdifferonz of 1O ⁰ C for heat transport pending. If the heat exchange in the boiler is not in the static state, the heat sorting takes place dynamically open after temperatures, for example, if its storage capacity for the heating zones MII is utilized.

Advantageously, the boiler is still versehon with a heat pump circuit. For this purpose, located on the top of the exhaust gas heat exchanger 1, an annular evaporator 11 and at the bottom of the heat transfer heat exchanger 2, an annular Verflüssiget 12. The outer heat pipes 3 of the exhaust gas heat exchanger 1 ends within the evaporator 11 and nadelförmlgo condenser tubes 15 in the heat carrier heat exchanger ends at the top of the condenser 12 and are only in operative connection with this. At the same time, the needle-shaped condenser tubes 15 are insulated in the heat carrier heat exchanger 2 up to the beginning of the heating zone III. Between the evaporator 11 and the condenser 12 of the compressor 13 and the expansion valve 14 is connected. The evaporator temperature is set to £ -1O ⁰ C, which causes a cooling of the exhaust gases to S 0 ° C. For the preparation of domestic hot water and for the operation of a Ntodertemperaturheizung If the condenser temperature set to + 50 ° C bia + 6O ⁰ C. The exhaust gas heat exchanger 1 thus works almost without heat loss.

The boiler according to the invention is characterized by a very high efficiency, in particular due to the heat sorting in the exhaust gas heat exchanger and in working as a stratified storage heat transfer heat exchanger. This also means saving primary energy. With the help of the heat pump cycle, the exhaust gases can be cooled to below the temperature of the heat carrier. But even without a heat pump cycle takes place as far as possible heat energy utilization of the exhaust gases. The emission of pollutants is greatly reduced for this boiler. In addition, the manufacturing costs, in particular the material costs, compared to its performance parameters are low. Another advantage of the boiler is its ease of repair. Even when operating with a heat pump cycle, the boiler has a high level of operational reliability and service life.

Claims (5)

A heating boiler equipped with heat pipes, characterized in that the boiler comprises an exhaust gas heat exchanger (1) having built-in, heat pipe (3) receiving a labyrinth plate heat exchanger (7) having a central exhaust gas inlet (5) and peripheral exhaust gas outlet (6), and a in the distance above it, equipped with the same continuous heat pipes (3) heat transfer heat exchanger (2), by horizontal, provided with openings partition plates (10) provided with different tempered Hftizzonen (I-IV) layered storage with one or more heat carrier - And-outs is formed. 2. Heating boiler according to claim 1, characterized in that the heating surface of the plate heat exchanger (7) surrounds the heat pipes (3) with a gap, in which thermally conductive powder (9 a) is introduced. 3. Heating boiler according to claim 1 or 2, characterized in that the heat pipes (3) in the region between the exhaust gas heat exchanger (1) and heat transfer heat exchanger (2) are insulated. 4. Heating boiler according to one of claims 1 to 3, characterized in that the heat pipes (3) within the heat transfer heat exchanger (2) are sheathed by a pipe with space, wherein in this space to associated heating zone (l-ll), graded from inside to outside, with the exhaust path insulating powder (9 b) is located and the remaining space is filled by thermally conductive powder (9 a). 5. Heating boiler according to one of claims 1 to 4, characterized in that on the top of the exhaust gas heat exchanger (1), an evaporator (11), equipped with from the exhaust gas heat exchanger (1) coming heat pipes (3), and at the bottom of the heat transfer heat exchanger (2) a condenser (12) operatively connected to partially insulated needle-shaped condenser tubes (15) in the heat transfer heat exchanger (2), and between the evaporator (11) and condenser (12) a compressor (13) including expansion valves (14) are switched.