DE19645475A1 - Heat exchanger for adsorber heat pump, cold energy machine or heat transformer working periodically - Google Patents

Abstract

The heat exchanger has at least two "sorbers" with tubes used as heat exchanger elements, with the heat of the adsorber transmitted for heating up and desorbing the desorber with minimal temperature differences between heat-carrying fluid, "sorber" material and sorption medium. There is a chamber in which a heat-carrying fluid flows and a chamber for the sorption medium connected to a further chamber in which the working vapour flows from an evaporator or to a condenser. The heat exchanger is built up from tubes provided with additional surfaces on one or both sides and the ratio of the additional area on both tube sides to the smooth outer tube surface is chosen to be large. A figure of 2 to 30 is understood. Good heat transmission with minimal volume is attained by minimal spacings of the components forming the surfaces of 0.5 to 10 millimetres, but preferably 1 to 4 millimetres. Thereby with minimal length and preferably only one pass-through, spatial counterflow is attained.

Description

The invention relates to a process engineering apparatus and in particular the in this apparatus used pipes according to the preamble of claim 1, with Solids, such as As silica gel, activated carbon, carbon molecular sieves, hydrides and preferably zeolites as adsorbent periodically working adsorption heat pumps, Adsorption chillers and adsorption heat transformers, with the description only relates to the application in adsorption heat pumps and adsorption chillers. With these sorption processes, the temperature differences of Condenser and evaporator temperature is a temperature range in which the adsorber temperature is equal to the desorber temperature in which a "spillover of the temperatures" takes place for one particularly effective heat exchange can be used. Not just cooling heat but also adsorption heat of the adsorber is transferred to a heat transfer fluid, which is a Liquid or a gas, in particular air or exhaust gas, can be transferred and transferred from the Transfer heat transfer fluid to the desorber.  

In order to achieve good heat transfer, the heat transfer fluid in the adsorber must be as possible are heated to a high level, for which purpose a countercurrent arrangement and small temperature differences between heat transfer fluid and adsorbent are prerequisites. The same applies to the Cooling of the heat transfer fluid in the desorber. The one caused by the high warming up low heat transfer rate per unit of time, it is difficult a pure countercurrent heat construct exchangers with high heat transfer coefficients.

In the case of adsorption heat pumps, the thermodynamically possible heating number is "overlap" of temperatures "at well over 2, but in only one publication (BWK, 47, (1995) No. 3, pp. 94-96) an adsorption heat pump with 2 adsorbers has been described works according to the patent specification DE 37 00 707 C2 and experimentally has a heating number of reached more than 2. However, this is equipped with sorber heat exchangers that consist of one several m long, one-sided wound pipe provided with enlarged surface, which had thermal short circuits due to contact with the winding and was therefore not optimal Could achieve countercurrent effect.

In the German application documents 195 22 250.4 and 195 39 154.3 a procedure for Operation of heat pumps and chillers described in the modified compact heat exchangers are used. It is a plate heat exchanger wheel sorber, for strength reasons only for a relatively small pressure difference between Heat transfer fluid side and sorbent side are suitable.

The invention is based, sorber heat exchanger for adsorption heat pump the task pen adsorption chillers or adsorption heat transformers with at least 2 Sorbering with tubes as heat exchanging elements with which heat of the or Adsorber for heating and desorption of the desorber (s) with low temperature  Differences between heat transfer fluid and sorbent with a small overall length and low Construction volume with heat transfer side preferably only one passage as countercurrent heat to specify exchangers in the essential design features. Even with low heat Carrier throughput should achieve good heat transfer with low pressure loss.

This object is achieved by the characterizing features of claim 1 solved.

The additional surfaces of the pipes should be economical and therefore largely used known technologies can be manufactured and operated.

This object is achieved by the characterizing features of claim 2 solved.

The heat flow in the flow axis of the heat transfer medium, preferably in the direction of Pipe axis lies in relation to the amount of heat transferred and at the same time lower Pipe length, which means a range from about 0.3 to 6 m, preferably up to 2 m and low heat capacity of the heat exchanger material is kept small. The bigger one Pipe length of 6 m is particularly useful for larger devices for design reasons. At the same time, due to the periodic operation, the Sorber's heat capacity is low he wishes.

According to the invention, this object is achieved by the characterizing features of claim 3 solved.

The pressure drop on the working medium side between the sorbent and the condenser or evaporator must in particular due to the resulting drop in temperature Sorber systems that work at low temperatures and pressures with water as the working medium work, be small. A favorable pressure loss with good heat transfer, the specified sorbent diameter range and the flow of sorbent height  reached. Furthermore, pressure losses due to changes in cross-section or redirection are said to occur be avoided.

According to the invention, these objects are achieved by the characterizing features of claims 4 and 5 solved.

The adsorber heat exchanger is designed for high operating temperatures resulting from thermodynamic Reasons above 230 ° C, preferably above 250 ° C, be suitable. Also for the practical Operation, it is advantageous if even higher temperatures are permitted for the heat exchanger can be. For example, zeolite can temporarily tolerate higher ones Temperatures such that the construction and control of a system designed for higher temperatures can be made more economical. Suitable for high temperatures with one-sided Pipes provided with enlarged additional surfaces are removed by rolling or drawing Solid material manufactured. Suitable pipes for high temperatures are also included welded smooth or interrupted round and longitudinal ribs on an industrial scale. Additional surfaces with particularly low material thicknesses are made with soft solders, which are already at Melt 183 ° C or at most 232 ° C, connected to pipes with good heat conduction. Soldering techniques, are known to work with soft solders or hard solders melting above 280 ° C usually not used for round tubes.

This object is achieved by the characterizing features of claim 6 solved.

In an embodiment of the invention are used for the construction of the Sorber heat exchanger preferably pipes that meet all the conditions for an axial flow of the heat transfer fluid meet, used. If liquids are used as heat carriers, the solution is included inside flow of the heat transfer fluid is often advantageous. The solution with an internal one Sorbent arrangement offers particular advantages when air or as a heat transfer fluid  Flue gases with low pressure are used and therefore a simple execution of the Heat transfer fluid space is possible. A cleaning of the heat transfer fluid space is with this Arrangement possible if the jacket of the heat transfer fluid space is made removable.

According to the invention, this object is achieved by the characterizing features of claim 7 solved.

With a heat transfer fluid that tends to contaminate the heat exchange surfaces, a Another arrangement can be selected that allows easy cleaning. An advantage of this Execution is that the method has no claims on the thermal conductivity of the Pipes provided with additional surfaces are placed, since these are perpendicular to the direction of flow of the heat transfer fluid are arranged.

This object is achieved by the characterizing features of claim 8 solved.

The advantageous use of the heat exchanger according to the invention is not specific to any one Circuit of the adsorption heat pump or chiller in which it is installed. An advantageous use only presupposes that for an adsorption heat pump or -Cooling machine required sorber heat exchanger switched and operated in counterflow will.

This object is achieved by the characterizing features of claim 9 solved.

Some manufacturers require an inner tube ( 19 ) to manufacture the tubes with ribs on both sides. This tube can be used, for example, advantageously for supplying heat by condensing steam or by cooling flue gases or for transferring heat of medium temperature as useful heat.

In many cases there is a limited amount of fluid per unit of time as a heat source and / or Heat sink available. In other words, the job is to get the fluid bigger Temperature range, for example more than 10 ° C to cool and / or heat.

This object is achieved by the characterizing features of claim 11.

The invention is described in more detail with reference to the following figures . It shows:

Fig. 1 is a group consisting of a tube with internal side Sorberwärmeaustauscher Sorptionsmittelanordnung,

Fig. 2 is a group consisting of a tube with exterior side Sorberwärmeaustauscher Sorptionsmittelanordnung,

Fig. 3 and Fig. 4 shows a form of a tube bundle apparatus Sorberwärmeaustauscher,

Fig. 5 and 6 on both sides provided with corrugated strips tube Fig.

Fig. 7 and Fig. 8 a both sides provided with wires tube,

FIGS. 9 and 10 a composed of perpendicular incident flow pipes to the pipe axis Sorberwärmeaustauscher FIG.

Fig. 11 A counterflow arrangement of Sorber heat exchangers.

In Fig. 1, a Sorber heat exchanger ( 1 ) consisting of a tube with an internal sorbent arrangement is shown schematically. On the inside of the tube ( 11 ) provided with enlarged surfaces on both sides, for example, wires are attached as additional surfaces ( 12 ), between which there is the sorbent ( 13 ), for example as a bed, which is vapor-permeable through a wire mesh, perforated plate or expanded metal ( 14 ) from Space in which the working fluid ( 15 ) flows is separated. If a coating of the sorber heat exchanger surface with sorbent is provided instead of the bed, the wire screen ( 14 ) can be omitted. On the outside of the tube ( 11 ), the heat transfer fluid ( 16 ) flows through the intermediate spaces of the additional surface ( 12 ) formed, for example, by wires. The jacket ( 17 ) delimiting the outside can move freely. In the event that atmospheric air or combustion exhaust gas is used as the heat transfer medium, this solution is particularly suitable. In this case, several pipes can easily be accommodated in a jacket ( 17 ) with a jacket cross section adapted to the available space. If the jacket is removable, cleaning on the heat transfer fluid side is possible.

It is here for the advantageous use of the sorber heat exchanger according to the invention regardless of the circuit only necessary that the heat transfer fluid on cooling Adsorber operation and in adsorber operation on one side and during preheating Desorption and in desorber operation on the other side of the sorber heat exchanger occurs, which creates a cold and a hot side.

When cooling to the adsorber temperature and when operating as an adsorber, the heat transfer fluid ( 16 ) and the working fluid vapor ( 18 ) flow in the direction of the arrow. The heat transfer fluid heats up through sensible heat from the cooling and heat of adsorption, for example from 20 ° C. to initially 220 ° C. and at the end of the adsorption period to, for example, 160 ° C. or less. When preheating for desorption and in operation as a desorber, the heat transfer fluid ( 16 ) and the working fluid vapor ( 18 ) flow counter to the direction of the arrow. The heat transfer fluid emerging from the adsorber is supplied with further heat and it enters the desorber on the hot side in the heat exchanger at a temperature of, for example, 180 ° C. to 240 ° C., cools down by giving off sensible heat and desorption heat to the desorber and occurs on the cold side with a temperature of initially 20 ° C and at the end of the heat exchange period, for example 80 ° C or warmer.

When operating with gaseous heat transfer fluids, heat transfer coefficients of 150 to 350 W / (m ² .K) and more can be economically achieved with atmospheric pressure and moderate pressure loss in relation to the outer surface of the pipe. When operating with liquids as a heat transfer medium, heat transfer coefficients of more than 400 W / (m ² .K) can be achieved economically. Tubes with a circular cross section are preferably used. However, tubes with other cross sections, such as oval cross section or rectangular cross section, can also be used if there are no excessive pressure differences between the adsorbent space and the heat transfer fluid space.

In Fig. 2, a Sorber heat exchanger ( 1 ) consisting of a tube with an outside sorbent arrangement is shown schematically. In this case, the sorbent ( 13 ) is housed on the outside of the tube ( 11 ) provided with enlarged surfaces ( 12 ) on both sides between wires. The bed is separated from the steam space ( 15 ) by a wire mesh, perforated plate or expanded metal ( 14 ). If a coating of the sorber heat exchanger surface with sorbent is provided instead of the bed, the wire screen ( 14 ) can be omitted. The jacket ( 17 ) delimiting the outside is connected to the inner tube ( 11 ) in a gas-tight manner. To compensate for the different thermal expansion, it can be designed with expansion compensation. On the inside of the tube ( 11 ), the heat transfer fluid ( 16 ) flows through the surface ( 12 ), for example enlarged by wires. The inner tube ( 19 ) is provided for manufacturing reasons, but can be used as an additional surface for heat exchange, for example heating with steam or cooling of combustion gases with indirect heating of the heat transfer fluid circuit. When cooling to the adsorber temperature and when operating as an adsorber, the heat transfer fluid ( 16 ) and the working fluid vapor ( 18 ) flow in the direction of the arrow. When operating as a desorber and when preheating for desorption, the heat transfer fluid ( 16 ) and the working fluid vapor ( 18 ) flow counter to the direction of the arrow.

Further details correspond to the explanations for FIG. 1.

In Fig. 3 and Fig. 4 a built-up of several parallel tubes Sorberwärmeaustauscher (1) is shown. It consists of the tubes ( 11 ) with an enlarged surface ( 12 ) on both sides, the sorbent filling ( 13 ), the wire screen, perforated plate or expanded metal ( 14 ) and the jacket ( 17 ). The tube ( 19 ) is not drawn. This arrangement is economical for large apparatuses in which the sorbent is located on the outside of the tubes.

With an appropriate design of the apparatus, the sorbent ( 13 ) can also be accommodated on the inside of the tubes ( 11 ). In particular when using a gaseous heat transfer fluid under normal pressure, an arrangement of the sorbent ( 13 ) on the inside of the tubes ( 11 ) is also useful, because then the heat transfer fluid can be guided on the pressure-unproblematic side.

Further details correspond to the explanations for FIGS. 1 and 2.

In Fig. 5 and Fig. 6 is a provided with surfaces arranged on both sides additional tube (11) is shown. As additional surfaces, corrugated strips ( 31 ) of, for example, 5 mm width, for example made of copper, brass or steel, are connected to the tube ( 11 ) by soldering or pressing with good thermal conductivity on the outside and inside. As a result, the exchange areas can be enlarged to approx. 3 to 20 times the outer pipe area. The inner tube ( 19 ) is required for manufacturing reasons. This tube is particularly suitable for axial flow. A radial flow through the sorbent layer is possible. Particularly when the sorbent is applied as a coating, other enlarged surfaces, such as transverse ribs, for example round ribs or helically applied ribs or longitudinal ribs, which are preferably interrupted in the axial direction, are advantageous on the sorbent side.

In Fig. 7 and Fig. 8 is a provided with surfaces arranged on both sides additional tube (11) is shown, on which surfaces as additional wires (32) are outside and inside soldered preferably made of copper. As a result, the exchange surfaces can also be enlarged to approx. 3-20 times the outer surface of the pipe. As an example, a tube made of wire mesh, perforated sheet metal or expanded metal ( 14 ) which is permeable to working fluid vapor is provided as the inner tube. This tube is equally suitable for an axial as for a radial flow. With this tube, different additional surfaces can be attached inside and outside.

In Fig. 9 and Fig. 10 is a constructed of vertically flows to the tube axis Sorberwärmeaustauscher pipes is shown. This structure has the advantage that no demands are made on the thermal conductivity of the tubes ( 11 ). The manifold ( 22 ) must have a low heat conduction in the flow axis of the heat transfer fluid, which is achieved by low wall thickness and choice of a material with low thermal conductivity, such as brass, copper-nickel control, steel or in particular chrome-nickel steel. If the jacket ( 17 ) is designed to be removable, the tubes can be easily cleaned on the heat transfer fluid side. The apparatus ( 5 ), which is used as a condenser and subsequently as an evaporator, is also shown. On the outside of the tubes ( 11 ), the heat transfer fluid flows past the additional surfaces ( 12 ), which achieve low flow resistance and good heat transfer when flowing perpendicular to the tube axis, such as spirally wound fins, round fins or rectangular fins. On the inside of the tubes, the sorbent ( 13 ) is housed on or between the additional surface ( 12 ). The tubes are connected to the header tube ( 22 ). In Fig. 6, the apparatus ( 5 ) is connected directly to the manifold 22 . A direct connection to the collecting pipe has the advantage of a lower pressure loss of the working medium ( 18 ).

An assignment from the respective adsorber to the evaporator and from the respective desorber to Capacitor is also possible if appropriate switch fittings are installed.

When cooling to adsorber temperature and in operation as an adsorber, the heat carrier fluid ( 16 ) and the working fluid vapor ( 18 ) flow in the direction of the arrow. In this phase, the apparatus ( 5 ) is connected to a heat source and evaporates the working fluid, which is adsorbed in the adsorber. During preheating for desorption and in operation as a desorber, the heat transfer fluid ( 16 ) and the working fluid vapor ( 18 ) flow against the direction of the arrow. In this phase, the apparatus ( 5 ) is connected to a heat sink and condenses the working medium desorbed from the desorber.

Further details correspond to the explanations for FIG. 1.

FIG. 11 shows a counterflow arrangement of sorber heat exchangers in a sorption heat pump or refrigeration machine. If a material flow is warmed up and / or cooled down by a greater temperature difference, this arrangement has the advantage that the temperature rise takes place in two stages and drive energy is saved. The additional outlay on equipment is low, since the adsorber heat exchanger consists of several elements anyway and can be accommodated in a common housing on the heat transfer fluid side. There are 4 sorber heat exchangers ( 101 , 102 , 103 , 104 ), a four-way valve ( 56 ), a conveyor for heat transfer fluid ( 55 ), a heat exchange device for medium temperature ( 57 ) and a heat exchange device for high temperature ( 58 ). The apparatuses ( 53 ) and ( 54 ) can, as shown in FIG. 11, be operated as an evaporator if the apparatus is designed appropriately and assigned in line with the heat source ( 62 ) and as a condenser when assigned to the heat sink ( 61 ) in line. If the cables are assigned to the heat sink ( 61 ), the apparatus ( 51 ) and ( 52 ) can be operated as condensers and if they are assigned to the heat source ( 62 ) as an evaporator.

In operation, cold heat transfer fluid is conveyed with the conveying device ( 55 ) via the 4-way valve ( 56 ) through the adsorbers ( 103 ) and ( 104 ) connected in parallel on the heat transfer fluid side, in which it heats up and the sorbers cool down. The sorbers ( 103 ) and ( 104 ) adsorb working medium which has been evaporated in the apparatus ( 53 ) and ( 54 ) working as an evaporator. In the heat exchange device ( 58 ), the heat transfer fluid is further heated by indirect heat exchange or by direct mixing with a hot heat flow and cools down in the desorbers ( 101 ) and ( 102 ), the desorbers heating up and desorbing working fluid which is in the apparatus ( 51 ) and ( 52 ), which work as capacitors, is condensed. The heat transfer fluid passes through the 4-way fitting ( 56 ) into the heat exchange device ( 57 ), in which it is cooled further by the release of useful heat and returns to the delivery device ( 55 ). If atmospheric air is used as the heat transfer fluid, the heat transfer fluid can be conducted directly into the atmosphere. The conveyor ( 55 ) then sucks air directly. The heat exchange device ( 57 ) can then be omitted. After loading the adsorbers ( 103 ) and ( 104 ) and desorption of the desorbers ( 101 ) and ( 102 ), the direction of delivery of the heat transfer fluid is switched with the 4-way valve ( 56 ). This turns the previous adsorbers into desorbers and the previous evaporators into condensers and vice versa. Approximately at the same time, the medium of the heat sink ( 61 ), which absorbed heat of condensation in the apparatus ( 51 ) and ( 52 ) by the new condensers ( 53 ) and ( 54 ) and the medium of the heat source ( 62 ), which in the apparatus ( 53 ) and ( 54 ) emitted heat by the new evaporators ( 51 ) and ( 52 ) promoted.

Claims (11)

1. sorber heat exchanger for a periodically working adsorption heat pump adsorption chiller or an adsorption heat transformer with at least 2 sorbers with tubes as heat-exchanging elements, with the heat of the adsorber or heaters for heating and desorption of the desorber or desorbers with small temperature differences between heat transfer fluid, sorber material and sorbent is transferred a space in which a heat transfer fluid flows and a space in which a sorbent is accommodated, which is connected to another space in a vapor-permeable manner, in which working fluid vapor flows from an evaporator or to a condenser, characterized in that the heat exchanger consists of one or more on both sides Tubes provided with additional surfaces is constructed, the ratio of the area of the additional surfaces both on the outside of the tube and on the inside of the tube to the smooth outer surface of the tube in the economical range Hmen is chosen large, which means a range of approx. 2 to 30 and good heat transfer with a small construction volume is achieved by small distances between the components forming the surfaces of 0.5-10 mm, preferably 1 to 4 mm, and thereby less Overall length is preferably achieved locally with only one passage on the heat transfer side. 2. Sorber heat exchanger according to claim 1, characterized in that on the Areas with a favorable ratio of flow resistance to heat transfer side Heat transfer and surfaces with largely free radial on the adsorbent side Passage for the working fluid steam, such as transverse ribs, in particular round ribs or  Rectangular ribs, longitudinal ribs preferably with interruptions, attached helically Corrugated bands or preferably wires are provided. 3. Sorber heat exchanger according to claim 1 and 2, wherein the heat transfer fluid in the direction the pipe axes flows, characterized in that the wall thickness of the pipes for Reduction in heat conduction is chosen small, which is due to the economic context small pipe diameter is possible and requires corrosion-resistant material, pipe material with low thermal conductivity such. B. copper-zinc alloys (brass), Copper-nickel alloys, steel or preferably chrome-nickel steel is chosen and that as additional surfaces also with thin walls, preferably surfaces with Interruptions in the direction of the tube axes, such as interrupted longitudinal ribs, helically attached corrugated tapes or preferably wires and on the Cross ribs can also be selected on the adsorbent side. 4. Sorber heat exchanger according to claim 1, 2 and 3, wherein the sorbent as Coating of the pipe and additional surfaces is attached or as a fill through a wire screen or perforated plate is separated from the working medium vapor space so that it is permeable to steam characterized in that the additional surface receiving the sorbent at a Sorbent diameter of 0.3 to 3 mm has a height of about 4 to 25 mm, the lower layer height with smaller dimensions of the sorbent and accordingly short distances between the components forming the additional surface is provided. 5. Sorber heat exchanger according to at least one of claims 1, 2, 3 or 4, characterized characterized in that the condenser is combined with the evaporator and directly with the  Working medium vapor space of the sorber is connected, being bad as a connecting material thermally conductive metal with a small wall thickness is selected. 6. Sorber heat exchanger according to at least one of claims 1, 2, 3, 4 or 5, characterized characterized in that for connecting the pipes to the additional surfaces above approx. 230 ° C, preferably soft solders or hard solders melting above 280 ° C. are used, although also on one side with ribs made of solid material or welded ribs or with other additional surfaces provided by additional surfaces on the other side can be completed. 7. Sorber heat exchanger according to at least one of claims 1 to 6, with a space in the the heat transfer fluid flows and a room in which the sorbent is housed is connected to another room in which the working fluid steam flows, permeable to steam, characterized in that it is constructed from one or more tubes, the Heat transfer fluid in the direction of the pipe axis on the inside or outside of the pipe flows and the sorber material is attached to the other side of the pipe, whereby to Cleaning a removable version of the jacket can be provided. 8. Sorber heat exchanger according to at least one of claims 1 to 6, with a space in where the heat transfer fluid flows and a room in which the sorbent is housed which is connected to another room in which the working fluid steam flows, permeable to steam is characterized in that it consists of at least 4, preferably more than 10 tubes is constructed, which are connected to a manifold for the working fluid, which is a has low heat conduction, the heat transfer fluid perpendicular to the pipe axis on the outside of the pipe  flows and the sorbent is attached to the inside of the tube and preferably a removable jacket is provided. 9. Installation of Sorber heat exchangers according to at least one of the preceding claims are built in a heat pump or refrigerator, characterized in that the Heat transfer fluid on one side when cooling to adsorber operation and in adsorber operation and during preheating for desorption and in desorber operation on the other side of the Sorber heat exchanger occurs, which forms a cold and a hot side. 10. Sorber heat exchanger according to at least one of the preceding claims with a space in which the heat transfer fluid flows and a space in which the sorbent is housed which is connected to a further space in which the working fluid vapor flows, characterized in that a further space ( 19 ) is used for heat exchange. 11. Adsorption heat pump or chiller with sorber heat exchangers after at least one of the preceding claims, characterized in that the steam rooms the adsorber and the desorber are divided into 2 or more separate rooms and on as many condenser and evaporator rooms are connected, which are preferably as Condenser-evaporators are formed.