DE102017219228A1 - Combined boiler operating and defrosting device - Google Patents

Abstract

The invention is based on a combined boiler operating and defrosting device at least defrosting at least one heat exchanger unit (34a, 34b), with at least one evaporator unit (12a, 12b) at least evaporating at least one working medium, with at least one generator unit (16a, 16b). at least to an expulsion of the working fluid, with at least one condenser unit (18a, 18b) at least to a condensation of the working fluid and with at least one valve unit, which is provided for a realization of a Abtaufunktion and a boiler operation.
It is proposed that the valve unit for realizing a Abtaufunktion and a boiler operation by means of a bypass of the condenser unit (18 a, 18 b) comprises a single valve element (32 a, 32 b) on an output line (36 a, 36 b), in particular hot gas line, the generator unit (16a, 16b) is arranged.

Description

State of the art

It is already a combined boiler operating and defrosting at least a defrost at least one heat exchanger unit, with at least one evaporator unit at least for evaporation of at least one working fluid, with at least one generator unit at least to a expulsion of the working fluid, with at least one capacitor unit at least to a condensation of the working fluid and with at least one valve unit provided for realizing a defrosting function and a boiler operation.

Disclosure of the invention

The invention is based on a combined boiler operating and defrosting device at least defrosting at least one heat exchanger unit, with at least one evaporator unit at least for evaporation of at least one working fluid, with at least one generator unit at least for expulsion of the working fluid, with at least one capacitor unit at least to a condensation the working fluid and with at least one valve unit, which is provided for a realization of a Abtaufunktion and a boiler operation.

It is proposed that the valve unit for realizing a defrost function and a boiler operation by means of a bypass of the condenser unit has a single valve element which is arranged on an outlet line, in particular on a hot gas line, of the generator unit.

The heat exchanger unit is preferably provided to transfer thermal energy, in particular in the form of heat, from a heat source to the combined boiler operating and defrosting device, in particular to the evaporator unit. By "provided" is intended to be understood in particular specially programmed, designed and / or equipped. The fact that an object is intended for a specific function should in particular mean that the object fulfills and / or executes this specific function in at least one application and / or operating state. In particular, a natural heat source can be used as the heat source. A natural heat source may in particular be a soil, a groundwater, an outside air or another heat source which appears expedient to a person skilled in the art. Alternatively, it is conceivable that an artificial heat source is used as the heat source. An artificial heat source may in particular be a waste heat of a device, a building and / or a plant, preferably in the form of a wastewater or an exhaust air. The heat exchanger unit may preferably be designed as a DC heat exchanger, a countercurrent heat exchanger, a crossflow heat exchanger or as another heat exchanger unit which appears expedient to a person skilled in the art.

Preferably, the heat exchanger unit transmits the heat received from the heat source to the evaporator unit. In the evaporator unit in particular a working fluid is evaporated. Preferably, a low pressure prevails in the evaporator unit, in particular a lower pressure than in a conduit through which the working fluid is supplied to the evaporator unit. In particular, due to the low pressure, the working fluid boils in the evaporator unit. In particular, the working fluid undergoes a phase transition from a liquid state of aggregation to a gaseous state of aggregation. Preferably, a working medium vapor is formed. In particular, a temperature of the working fluid decreases during a boiling process. Preferably, the temperature of the working fluid decreases to such an extent that the working fluid has a lower temperature than the evaporator unit which has been heated by the heat exchanger unit by means of the heat from the heat source. Preferably, the gaseous working fluid may receive heat from the evaporator unit. In particular, the evaporator unit can have heat transfer elements for heat transfer to the working medium. The heat exchanger elements can be designed, in particular, as lamellar heat exchanger elements or as other heat exchanger elements which appear sensible to a person skilled in the art. The working medium may preferably be in the form of a chlorinated or fluorinated hydrocarbon, carbon dioxide, ammonia, water or another working medium which appears expedient to a person skilled in the art. Alternatively, it is conceivable that the working medium is formed as a mixture of at least two different substances.

In the generator unit, the working fluid is preferably expelled, in particular expelled from a solvent. In particular, the working fluid may be dissolved in the solvent after absorption by the solvent, in particular in an absorber. The solvent may in particular be in the form of a salt solution, a water or another solvent which appears expedient to a person skilled in the art. Preferably, a solubility of the working fluid in the solvent is inversely proportional to the temperature of the working fluid. In particular, the solubility of the working fluid decreases with increasing temperature of the working fluid. In the generator unit is the working fluid preferably heated until the solubility of the working fluid is so low that a solution of the working fluid in the solvent is impossible. In particular, the working fluid is expelled from the solvent. Heat which supplies the generator unit to the working medium for heating preferably originates from a high-temperature heat source. The high-temperature heat source may in particular be designed as a gas burner, an oil burner, an electric heater or as another high-temperature heat source which appears expedient to a person skilled in the art. In a gas absorption heat pump, the heat for heating the working fluid preferably originates from a gas burner.

Preferably, the working medium vapor heated by the generator unit and expelled from the solvent flows to the condenser unit. In the condenser unit, the hot working medium vapor cools and condenses, whereby condensation heat is released. The working medium preferably undergoes a phase transition from a gaseous to a liquid state of aggregation. The condensation heat is preferably supplied to a heating system. The liquid working fluid flows from the condenser unit through an expansion valve element to the evaporator unit.

The combined boiler operating and defrosting device preferably comprises a valve unit having a single valve element through which the condenser unit can be bypassed. The single valve element may preferably be formed as a single valve. Preferably, the single valve may be a flow control valve, in particular an automatically controlled flow control valve, or another valve that appears expedient to a person skilled in the art. Preferably, by means of the individual valve element, the working medium, in particular the hot working medium vapor, can be passed from the generator unit directly to the evaporator unit, in particular without passing through the condenser unit. Preferably, the evaporator unit can be heated by the hot working medium vapor. In particular, the hot working medium vapor in the evaporator unit can cool and condense, with condensation heat preferably being produced. In particular, the heat of condensation generated in the evaporator unit can be transferred from the evaporator unit to the heat exchanger unit. Preferably, the heat exchanger unit, in particular an iced heat exchanger unit, can be defrosted.

Due to the heat absorption from the heat source by the heat exchanger unit preferably decreases the temperature of the heat source or a temperature of a fluid of the heat source. In particular, the temperature of the heat source or the fluid of the heat source can fall below a freezing point. Preferably, at a temperature below freezing point, moisture, in particular humidity, can condense and freeze on the heat exchanger unit. In particular, the heat exchanger unit can freeze. Preferably, by means of the individual valve element of the valve unit, a defrost function to a defrost of the heat exchanger unit can be realized.

In particular, conditions for heat transfer from the heat exchanger unit to the evaporator unit may be inappropriate. In particular, the temperature of the heat source may be too low for effective heat pump operation or a required heating power of the heating system may be too high compared to the heat supplied by the heat source. A "heat pump operation" is to be understood in particular an operating state in which the individual valve element of the valve unit is closed, wherein preferably the capacitor unit is flowed through by the working fluid. Preferably, under conditions unsuitable for heat transfer from the heat exchanger unit to the evaporator unit, the working fluid can only be heated by the generator unit. In particular, a "boiler operation" is to be understood as an operating state in which the working fluid is only heated by the generator unit. In particular, during a boiler operation, condensation and evaporation of the working medium can be dispensed with. Preferably, the capacitor unit can be bypassed by means of the individual valve element for realizing a boiler operation. Preferably, by means of the individual valve element, the working medium, in particular the hot working medium vapor, can be passed from the generator unit directly to the evaporator unit, in particular without passing through the condenser unit. Preferably, during a boiler operation, heat transfer between the evaporator unit and the heat exchanger unit may be interrupted, in particular by preventing circulation of a heat transfer fluid. In particular, the evaporator unit can be heated by the hot working medium vapor to a working temperature at which a condensation of the working medium vapor in the evaporator unit is omitted. Preferably, the hot working medium vapor can flow without condensation through the evaporator unit, which has the working temperature, in particular to flow to the absorber unit. Preferably, a boiler operation can be realized by means of the single valve element.

Due to the inventive design of the combined boiler operating and defrosting apparatus, in addition to a defrosting function, it is also advantageous to operate the boiler by means of a single boiler Valve element can be realized. Advantageously can be dispensed with a separate valve element for a boiler operation with an associated interconnection and control. Advantageously, a low-cost and low-maintenance combined boiler operating and defrosting device can be provided.

Furthermore, it is proposed that the evaporator unit has at least one heat transfer fluid line to a fluidic connection with the heat exchanger unit, wherein a fluid flow in the heat transfer fluid, in particular for a realization of a defrost function and a boiler operation, in dependence on a position of the individual valve element is adjustable. Preferably, the position of the single valve element is dependent on an operating condition of the combined boiler operating and defrosting device. The heat transfer fluid line may preferably be designed as a, in particular thermally insulated, pipe, as a hose or as another, which appears appropriate to a person skilled in heat transfer fluid. Preferably, the heat transfer fluid line may be formed as a circuit between the evaporator unit and the heat exchanger unit. In particular, a heat transfer fluid can flow, in particular circulate, in the heat transfer fluid line. The heat transfer fluid may preferably be formed as a water-glycol mixture, as water, in particular mixed with an antifreeze, as a salt solution or as another, appear to be appropriate to a skilled heat transfer fluid. The heat transfer fluid is in particular provided to transfer heat from the heat exchanger unit to the evaporator unit or to transfer heat from the evaporator unit to the heat exchanger unit. Preferably, heat is transferred from the heat exchanger unit to the evaporator unit during heat pump operation by means of the heat transfer fluid. Heat is preferably transferred from the evaporator unit to the heat exchanger unit in order to realize a defrosting function by means of the heat carrier fluid. Preferably, heat is not transferred from the evaporator unit or from the heat exchanger unit by means of the heat transfer fluid to realize a boiler operation.

In particular, in order to regulate the fluid flow in the heat transfer fluid line, a pump, a valve or another component that appears expedient to a person skilled in the art may be arranged in and / or on the heat transfer fluid line. The fluid flow in the heat carrier fluid line is preferably adjustable as a function of a position of the individual valve element. In particular, in the case of a closed position of the individual valve element, the fluid flow in the heat transfer fluid line can be released. Preferably, by means of the circulating heat transfer fluid, heat can be transferred from the heat exchanger unit to the evaporator unit to realize a heat pump operation. In particular, in the case of an open position of the individual valve element, the fluid flow in the heat carrier fluid line can be disconnected or switched off. Preferably, the fluid flow may be enabled to implement a defrost function. Preferably, to defrost the heat exchanger unit by means of the circulating heat transfer fluid, heat is transferred from the evaporator unit to the heat exchanger unit. Preferably, the fluid flow may be switched off to a boiler operation. Preferably, heat loss of the evaporator unit via the circulating heat transfer fluid can be prevented. It can be achieved an advantageous interaction of the individual valve element and the heat transfer fluid. Advantageously, a plurality of operating states of the combined boiler operating and defrosting device can be realized by means of combinations of fluid flows through the individual valve element and through the heat transfer fluid line. Advantageously, an efficient control of the combined boiler operating and defrosting device can be achieved.

It is also proposed that the individual valve element is provided for realizing a defrosting function and a boiler operation to fluidly connect the output line of the generator unit in an fluid flow direction to at least one expansion valve unit which fluidly connects the condenser unit and the evaporator unit to an input line of the evaporator unit , The fluid flow direction is particularly the direction in which the working fluid flows during a heat pump operation. In particular, the working fluid flows in a heat pump operation from the condenser unit to the evaporator unit. Preferably, the expansion valve unit has at least one expansion valve, which is in particular closed to realize a defrost function and a boiler operation. In particular, the hot working medium vapor may flow into the evaporator unit from the output line of the generator unit through the single valve element and through the inlet line of the evaporator unit, in particular without being blocked by the expansion valve. The output line of the generator unit and the input line of the evaporator unit can be designed, in particular, as pipelines, hose lines or other lines that appear appropriate to a person skilled in the art. Advantageously, an efficient interconnection of the generator unit with the evaporator unit and via the evaporator unit with the absorber unit can be achieved.

Furthermore, it is proposed that the individual valve element is provided for realizing a defrost function and a boiler operation to fluidly connect the output line of the generator unit to an output line of the evaporator unit. In particular, by connecting the output line of the generator unit to the output line of the evaporator unit, the condenser unit and the expansion valve closed, in particular to realize a defrost function and a boiler operation, can be bypassed. The outlet line of the evaporator unit is preferably designed as a pipeline, a hose line or another line that appears appropriate to a person skilled in the art. Preferably, in particular for a realization of a defrosting function, the hot working medium vapor can flow from the output line of the generator unit through the individual valve element and the outlet line of the evaporator unit into the evaporator unit. Preferably, in particular for a realization of a boiler operation, the hot working medium vapor can flow from the output line of the generator unit through the individual valve element and the outlet line of the evaporator unit into the absorber unit.

Furthermore, it is conceivable that the individual valve element is designed as a three-way valve, which can fluidly connect the output line of the generator unit with both the input line of the evaporator unit and with the output line of the evaporator unit. Preferably, by means of the three-way valve, a working medium flow can be set optimized for an operating state. In particular, the output line of the generator unit can be fluidly connected to the input line of the evaporator unit by means of the three-way valve to realize a Abtaufunktion, in particular to prevent a countercurrent of gaseous and liquid working fluid in the output line of the evaporator unit. In particular, the output line of the generator unit can be fluidly connected to the outlet line of the evaporator unit by means of the three-way valve for realizing a boiler operation, in particular in order to keep a working medium flow through the evaporator unit low. Advantageously, various interconnection options can be provided for a realization of a defrost function and a boiler operation.

In addition, the invention is based on a method for operating a combined boiler operating and defrosting device, in particular a boiler operating and defrosting device according to the invention.

It is proposed that, in particular in at least one method step, to realize a defrost function and a boiler operation by means of a single valve element at least one capacitor unit is bypassed. Preferably, by means of the single valve element, the condenser unit and an expansion valve unit can be bypassed. Advantageously, a boiler operation can be realized by means of the individual valve element in addition to a Abtaufunktion. Advantageously can be dispensed with a separate valve element for a boiler operation with an associated interconnection and control.

Furthermore, it is proposed that, in particular in at least one method step, to realize a boiler operation by means of a single valve element, a fluidic connection of at least one output line of at least one generator unit with at least one input line or at least one output line of at least one evaporator unit is produced. Preferably, a fluidic connection of the output line of the generator unit to the input line or to the output line of the evaporator unit can also be produced for a realization of a defrost function by means of the individual valve element. Advantageously, different connection possibilities of the generator unit with the evaporator unit, in particular for the realization of a boiler operation, can be achieved by means of the individual valve element.

Furthermore, it is proposed that, in particular in at least one method step, thermal energy be transferred from the generator unit to the evaporator unit for realizing a boiler operation by means of at least one working medium. Preferably, a transfer of thermal energy from the evaporator unit to the heat exchanger unit remains. Preferably, the evaporator unit is heated to a working temperature at which a condensation of the working fluid fails. Preferably, after reaching the working temperature by means of the working medium, thermal energy is transported through the evaporator unit. Preferably, thermal energy can also be transmitted from the generator unit to the evaporator unit for realizing a defrosting function by means of the working medium. In particular, thermal energy can be transmitted from the evaporator unit to the heat exchanger unit for realizing a defrosting function by means of the heat transfer fluid. Preferably, by means of the working medium, thermal energy in the form of heat can be transmitted from the generator unit to the evaporator unit. Advantageously, an efficient heat transfer between the generator unit and the evaporator unit can be achieved.

Furthermore, it is proposed that, in particular in at least one method step, to realize a boiler operation, a fluid flow in at least one heat transfer fluid line is prevented. Advantageously, a transfer of the evaporator unit via the individual valve element supplied by the generator unit heat to the heat exchanger unit can be prevented. Advantageously, it is possible to dispense with a further valve element to bypass the evaporator unit to realize a boiler operation.

In addition, the invention is based on a heat pump, in particular a gas absorption heat pump, with at least one heat exchanger unit and with at least one combined boiler operating and defrosting device according to the invention. Preferably, the heat exchanger unit as a geothermal probe, a ground register, a geothermal basket, a water-heat exchanger, in particular groundwater heat exchanger, an air heat exchanger, in particular with at least one fan, a solar collector or as another, a specialist appear appropriate sense heat exchanger unit , In particular, the heat pump may have further, necessary for operation of the heat pump components. Preferably, the heat pump can have further lines, in particular to a connection of the heat pump to a heating system, a controller, a housing and further, a person skilled in the appear reasonable components. Advantageously, a flexibly applicable, inexpensive and low-maintenance heat pump can be provided.

The combined boiler operating and defrosting apparatus according to the invention, the method according to the invention and / or the heat pump according to the invention should / should not be limited to the application and embodiment described above. In particular, the combined boiler operating and defrosting device according to the invention, the method according to the invention and / or the heat pump according to the invention may have a number deviating from a number of individual elements, components and units and method steps mentioned herein for performing a function described herein. In addition, in the value ranges indicated in this disclosure, values lying within the stated limits are also to be disclosed as disclosed and used as desired.

list of figures

Further advantages emerge from the following description of the drawing. In the drawing, two embodiments of the invention are shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

• 1 eine erfindungsgemäße Wärmepumpe in einer schematischen Darstellung,
• 2 eine erfindungsgemäße kombinierte Kesselbetriebs- und Abtauvorrichtung in einer schematischen Darstellung und
• 3 eine alternative erfindungsgemäße kombinierte Kesselbetriebs- und Abtauvorrichtung in einer schematischen Darstellung.

Show it:

• 1 a heat pump according to the invention in a schematic representation,
• 2 a combined boiler operating and defrosting device according to the invention in a schematic representation and
• 3 an alternative combined boiler operating and defrosting device according to the invention in a schematic representation.

Description of the embodiments

1 shows a heat pump according to the invention 56a in a schematic representation. The heat pump 56a is formed as a gas absorption heat pump. The heat pump 56a comprises a combined boiler operating and defrosting device according to the invention 10a and a heat transfer unit 34a , The combined boiler operating and defrosting device 10a is inside a housing unit 58a the heat pump 56a arranged and indicated by a rimmed with a dashed line area. The heat exchanger unit 34a is outside the housing unit 58a arranged. The heat exchanger unit 34a is via a heat transfer fluid line 42a with the combined boiler operating and defrosting device 10a connected.

2 shows the combined boiler operating and defrosting device 10a in a schematic representation. The combined boiler operating and defrosting device 10a includes an evaporator unit 12a , an absorber unit 14a , a generator unit 16a and a capacitor unit 18a , Furthermore, the combined boiler operating and defrosting device 10a an expansion valve unit with an expansion valve element 20a on. The expansion valve element 20a connects an output line 22a the condenser unit 18a fluidly with an input line 24a the evaporator unit 12a , The combined boiler operating and defrosting device 10a also includes a solvent valve unit with a solvent valve element 26a , The solvent valve element 26a connects a solvent exit line 28a the generator unit 16a fluidly with a solvent inlet line 30a the absorber unit 14a ,

Furthermore, the combined boiler operating and defrosting device 10a a valve unit with a single valve element 32a on. The single valve element 32a connects to a realization of a defrost function for a heat exchanger unit 34a and to a realization of a Boiler operating an output line 36a the generator unit 16a fluidly with the input line 24a the evaporator unit 12a , The single valve element 32a is at the output line 36a the generator unit 16a arranged. The single valve element 32a connects the output line 36a the generator unit 16a in a fluid flow direction 38a considered after the expansion valve unit with the expansion valve element 20a fluidly with the input line 24a the evaporator unit 12a , A pump unit 40a conveys a not further shown working fluid along the fluid flow direction 38a , The pump unit 40a is designed as a circulation pump.

The evaporator unit 12a is intended for a heat pump operation to evaporate the working fluid. The evaporator unit 12a is by means of a heat carrier fluid, not shown on the heat transfer fluid 42a the evaporator unit 12a Heat from the heat exchanger unit 34a fed. The heat comes from a heat source not shown. The heat transfer fluid is from a further pump unit 44a through the heat transfer fluid line 42a promoted. The further pump unit 44a is designed as a circulation pump. The heat transfer fluid line 42a is as a circuit between the evaporator unit 12a and the heat exchanger unit 34a formed in which circulates the heat transfer fluid.

A working medium steam flows from an output line 46a the evaporator unit 12a via an input line 48a the absorber unit 14a in the absorber unit 14a , In the absorber unit 14a the working fluid is absorbed in a solvent not shown. The solvent with the dissolved working fluid flows from an output line 50a the absorber unit 14a via the pump unit 40a and an input line 52a the generator unit 16a in the generator unit 16a ,

In the generator unit 16a the solvent is heated with the working fluid by means of heat of a high-temperature heat source, not shown. The working fluid is expelled from the solvent. The solvent flows over the solvent exit line 28a the generator unit 16a over the solvent valve element 26a and the solvent input line 30a the absorber unit 14a in the absorber unit 14a , In a heat pump mode, the single valve element is 32a the valve unit closed. The working fluid flows through the outlet line as hot working medium vapor 36a the generator unit 16a and an input line 54a the condenser unit 18a in the condenser unit 18a , In the condenser unit 18a Cools the working fluid vapor and condenses. A resulting condensation heat is supplied to a heating system not shown. The liquid working fluid flows from the outlet pipe 22a the condenser unit 18a over the expansion valve element 20a and the input line 24a the evaporator unit 12a in the evaporator unit 12a ,

The fluid flow of the heat transfer fluid in the heat transfer fluid line 42a is to a realization of a Abtaufunktion and a boiler operation in response to a position of the individual valve element 32a adjustable. In a heat pump mode, the valve element is 32a closed and the other pump unit 44a conveys the heat transfer fluid through the heat transfer fluid line 42a , It can generate heat from the heat exchanger unit 34a to the evaporator unit 12a be transmitted.

One realization of a defrost function is the expansion valve element 20a closed and the single valve element 32a open. The further pump unit 44a conveys the heat transfer fluid through the heat transfer fluid line 42a , The hot working medium vapor can via the output line 36a the generator unit 16a , the single valve element 32a and the input line 24a the evaporator unit 12a in the evaporator unit 12a stream. The condenser unit 18a and the expansion valve element 20a the expansion valve unit are bypassed. In the evaporator unit 12a gives the working fluid by condensation heat to the heat transfer fluid. By means of the heat transfer fluid, the heat to the heat exchanger unit 34a to a defrost of the heat exchanger unit 34a be transmitted.

One implementation of boiler operation is the expansion valve element 20a closed and the single valve element 32a open. The further pump unit 44a is switched off. A transport of the heat transfer fluid through the heat transfer fluid line 42a Stay off. The hot working medium vapor can via the output line 36a the generator unit 16a , the single valve element 32a and the input line 24a the evaporator unit 12a in the evaporator unit 12a stream. The condenser unit 18a and the expansion valve element 20a the expansion valve unit are bypassed. Due to a lack of circulation of the heat transfer fluid eliminates a transfer of heat from the hot working medium vapor to the heat exchanger unit 34a by means of the heat transfer fluid. The hot working medium vapor condenses only until the evaporator unit 12a is heated to a working temperature at which a condensation due to a lack of temperature difference between the working medium vapor and the evaporator unit 12a absent. To realize a boiler operation, the hot working agent vapor may be the evaporator unit 12a flow through and over the output line 46a the evaporator unit 12a and the input line 48a the absorber unit 14a in the absorber unit 14a flow and be absorbed there. A released by an absorption heat is transferred to a not shown heating system.

In the 3 a further embodiment of the invention is shown. The following description and the drawings are essentially limited to the differences between the exemplary embodiments, with respect to identically named components, in particular with regard to components having the same reference numerals, in principle also to the drawing and / or the description of the other embodiment, in particular 1 and the 2 can be referenced. To distinguish the embodiments of the letter a is the reference numerals of the embodiment in the 1 and 2 readjusted. In the embodiment of 3 the letter a is replaced by the letter b.

3 shows a combined boiler operating and defrosting device according to the invention 10b in a schematic representation. The combined boiler operating and defrosting device 10b comprises a valve unit with a single valve element 32b to a realization of a defrost function and a boiler operation by means of a bypass of a condenser unit 18b on. The single valve element 32b is on an output line 36b a generator unit 16b arranged. The single valve element 32b connects the output line 36b the generator unit 16b fluidly with an output line 46b an evaporator unit 12b ,

A fluid flow of a heat transfer fluid in a heat transfer fluid line 42b is to a realization of a Abtaufunktion and a boiler operation in response to a position of the individual valve element 32b adjustable. In a heat pump mode, the single valve element is 32b closed and another pump unit 44b conveys the heat transfer fluid through the heat transfer fluid line 42b , It can generate heat from a heat exchanger unit 34b to the evaporator unit 12b be transmitted.

One realization of a defrost function is an expansion valve element 20b closed and the single valve element 32b open. The further pump unit 44b conveys the heat transfer fluid through the heat transfer fluid line 42b , A hot working fluid vapor may be via the output line 36b the generator unit 16b , the single valve element 32b and an output line 46b the evaporator unit 12b in the evaporator unit 12b stream. The condenser unit 18b and the expansion valve element 20b an expansion valve unit are bypassed. In the evaporator unit 12b gives a working fluid by condensation heat to the heat transfer fluid from. In the output line 46b the evaporator unit 12b there is a counterflow of liquid and gaseous working fluid. By means of the heat transfer fluid, the heat to the heat exchanger unit 34b to a defrost of the heat exchanger unit 34b be transmitted.

One implementation of boiler operation is the expansion valve element 20b closed and the single valve element 32b open. The further pump unit 44b is switched off. A transport of the heat transfer fluid through the heat transfer fluid line 42b Stay off. The hot working medium vapor can via the output line 36b the generator unit 16b , the single valve element 32b and the output line 46b the evaporator unit 12b in the evaporator unit 12b stream. The condenser unit 18b and the expansion valve element 20b the expansion valve unit are bypassed. Due to a lack of circulation of the heat transfer fluid eliminates a transfer of heat from the hot working medium vapor to the heat exchanger unit 34b by means of the heat transfer fluid. The hot working medium vapor condenses only until the evaporator unit 12b is heated to a working temperature at which a condensation due to a lack of temperature difference between a condensation temperature of the working medium vapor and the evaporator unit 12b absent. To realize a boiler operation, the hot working agent vapor may be the evaporator unit 12b flow through and over the output line 46b the evaporator unit 12b and an input line 48b the absorber unit 14b in an absorber unit 14b stream. At the same time, the hot working medium vapor can pass over the single valve element 32b and the input line 48b the absorber unit 14b directly into the absorber unit 14b stream.

The following is a method of operating the combined boiler operating and defrosting device 10a . 10b described. In at least one method step, a realization of a defrost function and a boiler operation by means of the individual valve element is achieved 32a . 32b the condenser unit 18a . 18b bypassed. In at least one further method step, a realization of a boiler operation by means of the individual valve element is achieved 32a . 32b a fluidic connection of the output line 36a . 36b the generator unit 16a . 16b with the input line 24a . 24b or with the output line 46a . 46b the evaporator unit 12a . 12b manufactured. In at least one further method step, thermal energy is generated by the generator unit for realizing a boiler operation by means of the working medium 16a . 16b to the evaporator unit 12a . 12b transfer. In at least one further method step, a fluid flow in at least one heat carrier fluid line becomes a realization of a boiler operation 42a . 42b prevented. With regard to further method steps of the method for operating the combined boiler operating and defrosting device 10a . 10b may refer to the previous description of the combined boiler operating and defrosting device 10a . 10b This description shall be read analogously to the method and thus all the characteristics of the combined boiler operating and defrosting device 10a . 10b also with regard to the method of operation of the combined boiler operating and defrosting device 10a . 10b to be considered revealed.

Claims (9)

Combined boiler operating and defrosting device at least for defrosting at least one heat exchanger unit (34a, 34b), with at least one evaporator unit (12a, 12b) at least for evaporation of at least one working medium, with at least one generator unit (16a, 16b) at least for expulsion of the working medium , with at least one condenser unit (18a, 18b) at least for condensation of the working fluid and with at least one valve unit intended for realizing a defrosting function and a boiler operation, characterized in that the valve unit is able to realize a defrosting function and a boiler operation by means of a Bypassing of the condenser unit (18 a, 18 b) has a single valve element (32 a, 32 b), which on an output line (36 a, 36 b), in particular hot gas line, the generator unit (16 a, 16 b) is arranged. Combined boiler operating and defrosting device according to Claim 1 , characterized in that the evaporator unit (12a, 12b) at least one heat transfer fluid line (42a, 42b) to a fluidic connection with the heat exchanger unit (34a, 34b), wherein a fluid flow in the heat transfer fluid (42a, 42b), in particular for a realization a Abtaufunktion and a boiler operation, in dependence on a position of the individual valve element (32a, 32b) is adjustable. Combined boiler operating and defrosting device according to Claim 1 or 2 characterized in that the single valve member (32a, 32b) is provided for realizing a defrosting function and a boiler operation, the output line (36a, 36b) of the generator unit (16a, 16b) in a fluid flow direction (38a) viewed after at least one expansion valve unit fluidly connecting the condenser unit (18a, 18b) and the evaporator unit (12a, 12b) to fluidly connect to an input line (24a, 24b) of the evaporator unit (12a, 12b). Combined boiler operating and defrosting device according to one of the preceding claims, characterized in that the individual valve element (32a, 32b) is provided for realizing a defrost function and a boiler operation, the output line (36a, 36b) of the generator unit (16a, 16b) fluidly with an output line (46a, 46b) of the evaporator unit (12a, 12b) to connect. Method for operating a combined boiler operating and defrosting device, in particular a combined boiler operating and defrosting device (10a, 10b) according to one of the preceding claims, characterized in that in at least one method step to realize a defrosting function and a boiler operation by means of a single valve element (32a , 32b) at least one capacitor unit (18a, 18b) is bypassed. Method according to Claim 5 , characterized in that in at least one method step to a boiler operation by means of a single valve element (32a, 32b), a fluidic connection of at least one output line (36a, 36b) at least one generator unit (16a, 16b) with at least one input line (24a, 24b ) or with at least one output line (46a, 46b) of at least one evaporator unit (12a, 12b) is produced. Method according to Claim 5 or 6 , characterized in that thermal energy is transferred from the generator unit (16a, 16b) to the evaporator unit (12a, 12b) in at least one method step for realizing a boiler operation by means of at least one working means. Method according to one of Claims 5 to 7 , characterized in that in at least one method step to a realization of a boiler operation, a fluid flow in at least one heat transfer fluid line (42a, 42b) is prevented. Heat pump, in particular gas absorption heat pump, with at least one heat exchanger unit (34a, 34b) and with at least one combined boiler operating and defrosting device (10a, 10b) according to one of Claims 1 to 4 ,

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