ES2224809B1 - COLD GENERATION AND HEAT RECOVERY DEVICE. - Google Patents

Abstract

Device for generating cold and heat recovery, based on the thermal use of heat from a cogeneration system, transmitted through the exhaust gases. Said device comprises a cogeneration module (1); an absorption machine (2); a boiler (3); and flow control elements (22), all components can be mounted on the same bench. It allows to improve the balance of energy used with respect to the energy consumed in the device for generating cold and heat recovery.

Description

Cold generation and recovery device of heat

Technical sector of the invention

The invention relates to a device of cold generation and heat recovery, based on the thermal use of heat from a cogeneration system, transmitted through the exhaust gases.

Background of the invention

They are known to a person skilled in the art existing techniques based on using heat systems cogeneration, in part or in its entirety, to heat the generator of an absorption system for cold production.

The operation of an absorption system is based on the affinity that, among them, have certain substances, so the chemical absorption process is favored, and at the same time, if they have very different boiling points, it is facilitated its separation by heating the mixture. One of the substances (the most volatile) acts as a refrigerant because it evaporates and cools the water of the air conditioning circuit while the other substance acts as absorbent of the first and the mixture resulting is pumped to the generator or heat generators, where by an external heat source (which in the present case is the heat of a cogeneration system) the substances are separated, the refrigerant condenses and subsequently expands and evaporates, starting the process again.

The process of taking advantage of the heat available due to engine cooling (shirts, oil and mixture), obtained in the form of hot water and about maximum temperatures ranging between 85 and 110ºC, with which It can produce hot air, water for heating, ACS, etc, and even, by incorporating an absorption machine, take advantage of this heat for the production of cold (trigeneration), Usable for air conditioning, cooling, water cooling, cold rooms, etc.

However, the known embodiments that are based on the direct use of heat from the gases of thermal engine exhaust, do not meet the characteristics efficiency and power required to be installed in buildings An example of known embodiments is the document ES 2159250, which describes a double effect absorption machine air-cooled and heat-fed from exhaust gases of thermal motors and their application procedure for air conditioning, particularly applicable to provide service of air conditioning to a vehicle.

Thus, it is noted the lack of a device that meets the demand for cold and heat in mixed situations and, at the same time, recover to a greater extent the heat energy of the exhaust gases provided a adequate service to a local or building.

Explanation of the invention.

In order to improve the efficiency of existing devices, the device is disclosed cold generation and heat recovery object of the invention.

The cold generating device and heat recovery, is based on the thermal use of heat of a cogeneration system, transmitted through the exhaust gases, comprising a cogeneration module, coupled to an electric generator to produce electric power; a absorption machine, for the generation of cold; a boiler of recovery, for the recovery of heat from gases escape and some elements of flow control, connection and communication, all arranged so that the system is capable to automatically adapt to variations in the demand for cold, while recovering residual heat.

According to a preferred embodiment, the device is characterized because the connections between the module Cogeneration, absorption machine and recovery boiler they comprise a flow regulating element, adapted to receive the gases released by the cogeneration module through a conduit and provided with at least two external outputs, being able to regulate the amount of gases to be directed by each of the outputs, with at least one first output connected to a duct attached to the generator's inlet of the machine absorption, and a second outlet connected to a conduit attached to the heat exchanger inlet; a junction between the generator output and an intermediate interconnection point located in the conduit that joins the flow regulator and the heat exchanger; and a shot regulation element located at any point defined between said intermediate point of interconnection and expulsion of fumes abroad, through the chimney, after passing through the exchanger.

According to another feature of the invention, the device is provided with a flow control means, arranged between the flow regulator element and said intermediate point of interconnection, increasing the regulation accuracy of the device.

According to an embodiment preferably, the flow control means is a valve of the type guillotine. According to another feature of the invention, the cold generation and heat recovery device is equipped with a flow regulating device, arranged between the intermediate interconnection point and exchanger inlet of heat, to be able to evacuate the gases to the outside in case of emergency.

According to another feature of the invention, the draft regulation element is a fan located at the exit of heat recovery.

According to one embodiment, the Cogeneration module comprises a gas or diesel turbogenerator whose exhaust gases, at nominal rate, have a temperature between 275ºC and 650ºC and an oxygen content between 15% and 19% in volume.

According to another embodiment, the module cogeneration comprises a gas generator that runs on gas natural as fuel, the exhaust gases of which have a temperature, at nominal rate, between 440ºC and 530 ° C.

According to a preferred embodiment, the device is mounted on the same bench, forming a compact set for generating cold, electricity and heat.

The characteristics described above of device for generating cold and heat recovery of the invention, provide an increase in the efficiency of a cold generator, electricity and heat recovery system, since the systems can work separately, according to the needs, or in series, so that even deriving 100% of The output of gases for maximum cold production, can be recover the residual heat in the recovery boiler to to heat water.

Brief description of the drawings

A preferred embodiment of the heat generation and cold generation device is shown in the accompanying drawings. In the only figure of said drawings, a scheme of the device of the invention is illustrated, in which the direction of circulation of the exhaust gases is indicated by
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Detailed description of the drawings

The following description refers to the drawings explained above, which allow us to appreciate in detail the different parts of which the generation device is formed of cold and heat recovery of the invention and illustrating a preferred embodiment of the device, based on the thermal use of a cogeneration module powered by a turbogenerator 1, which produces electrical energy 6. The turbogenerator is a rotary machine formed by a compressor of air attached to a power turbine and an electric generator by the same axis, whose exhaust gases have a high temperature, which can reach up to 650ºC, as well as a high content of oxygen, between 15% and 19%, due to the high ratio Air / fuel used.

There is also the possibility of further increase the temperature of the exhaust gases, performing a process of post-combustion (8) of said gases taking advantage of their oxygen content Thus, the outlet temperature of the Exhaust gases can rise to a maximum temperature of 1,100 ° C thus obtaining greater cooling power and heat recovery in the device of the invention.

This would be an option to take into account in the If you have a microturbine, the exhaust gases from the which have an outlet temperature of about 275 ° C. Result of a post-combustion process, carried out by example with an air vein burner and where the exhaust gases they act as oxidizer, the outlet temperature can reach 1,100 ° C.

Although not represented in the drawings, the cogeneration module 1 can also be an alternative engine of internal combustion in Otto cycle, running on natural gas as fuel. In this case, the exhaust gases can reach up to 500ºC and the engine exhaust gas treatment, It is the same as described in the case of the turbine.

The exhaust gases of the turbine are conducted through the conduit 12 towards the flow regulating element 22, provided with two external outputs connected to conduits 13 and 14, in turn connected to the input of the machine generator absorption 2 and at the inlet of heat exchanger 3, respectively.

The flow regulating element 22 acts as a exhaust gas distribution valve, so that the drift to absorption machine 2 if energy is required refrigerator, or to the heat exchanger or boiler of recovery 3 if thermal energy is required.

When there is a need for cooling energy, Exhaust gases are taken to the generator of the machine absorption 2, which by means of an internal process cools the water of consumption or fluid of an air conditioning circuit 23. At the exit of the absorption machine, the gases are conducted through the conduit 15 towards heat exchanger 3 to heat a secondary water circuit 24. It should be noted that, although the total exhaust gas flow is derived in the element regulator 22 towards the absorption machine 2, (maximum situation cold demand), due to the arrangement of the invention it is possible  recover thermal energy in exchanger 3, since the Exhaust gas outlet temperature is still usable, resulting in a final energy balance surprisingly higher than Conventional systems

When the demand is 100% heat, the flow element 22 derives the exhaust gases, in its entirety, towards the heat exchanger 3, where the heat of the gases from Exhaust is transmitted to the hot water circuit 24.

When the device works in response to a maximum heat or cold demand, the regulating element drifts at 100% exhaust gases to heat exchanger 3 or to the absorption machine 2. For better control of the gas distribution, the device is provided with a valve guillotine 17 between the flow regulator element 22 and the point of interconnection 16. To avoid back pressures greater than admitted by the turbine, the device is equipped with an element of shot regulation 4 located at any defined point between the connection point 16 of the conduits 14 and 15 and the expulsion to outside of the fumes, through chimney 5, after passing through the  exchanger 3. In the realization of the drawings, the element of draft regulation is a fan located at the exit of the heat recuperator 3, which sucks the exhaust gases in the direction towards the fireplace 5.

Between the intermediate point of interconnection and the entrance to the recovery boiler, there is another regulator of flow 25, to be able to extract the fumes outwards in case emergency through the emergency chimney 7.

When the regulating element 22 derives the exhaust gases from turbogenerator 1, in whole or in part significant, towards the absorption machine, the production of heat or cold of the device of the invention, is regulated automatically according to the user's demand, since the thermal losses of the exhaust gases inside the Absorption machine depend on the demand for cold. This way, exhaust gases depending on the demand for cold they will yield more or less energy, and being the heat exchanger 3  connected to the output of the absorption machine 2, the energy remaining will be used in the form of hot water destined for ACS, heating, etc.

This device regulation mode adapts much better to the needs of existing systems in terms of to its installation in sports complexes, hospitals, hotels, offices, shopping centers, etc., since in such facilities the relationship between the climate or the variation of the outside temperature, over a period of time, and the final demand for heat or cold, and it is also known that, in the tertiary or service sector, a type of energy demand is complementary to the other, so that in cold seasons there is a high demand for heat and a much lower demand for cold, in so much so that in hot periods the demand for cold exceeds Much to heat demand. A device of the characteristics of the device of the invention, would respond perfectly to a situation like this, since the intrinsic flexibility of the system is fits perfectly to the thermal needs of users, besides always producing electricity independently of thermal use of exhaust gases.

Although not indicated in the drawings, the actuation of the regulatory element 22, diverting in greater or lesser measured the exhaust gases through conduit 13 or 14, you can function from an external signal (such as the outside temperature, the water flow of the circuit air conditioning, the comfort temperature chosen by a hypothetical user, etc.), so that based on the value of said signal and the accumulated operational experience of the subsystems that make up the device, you get an amazing performance of this last, whose balance of energy harnessed with respect to the energy consumed is extraordinarily better than that of usual systems.

The device of the invention can be mounted by modules, so that the cogeneration module 1, the machine absorption 2 and heat exchanger 3 can form a compact set

Claims (9)

1. Cold generating device and heat recovery, based on the thermal use of heat of a cogeneration system, transmitted through the exhaust gases, comprising a cogeneration module (1), coupled to an electric generator to produce electric power; an absorption machine (2), for the generation of cold; a recovery boiler (3), for heat recovery from of exhaust gases; and flow control elements, connection and communication, all arranged so that the system is able to adapt automatically to the variations of the demand for cold and recovering residual heat. 2. Device according to claim 1, characterized in that the connections between the cogeneration module (1), the absorption machine (2) and the recovery boiler (3) comprise: a) A flow regulator element (22), adapted to receive the gases released by the cogeneration module (1) through a conduit (12) and provided with at least two outputs external, being able to regulate the amount of gas to be directed by each of the outputs, being connected at least a first outlet to a conduit (13), connected to the generator's inlet of the absorption machine (2), and a second outlet connected to a conduit (14) attached to the heat exchanger inlet (3); b) a connecting duct (15) between the outlet of the generator (2) and an intermediate point (16) of the duct (14) located between the flow regulator (22) and the heat exchanger heat (3); Y c) a draft regulation element (4) located at any point defined between the connection point (16) of the ducts (14) and (15), and the expulsion outside the fumes, to through the chimney (5), after passing through the exchanger (3). 3. Device according to the preceding claims, characterized in that it is provided with a flow control means (17), arranged between the flow regulator element (22) and the interconnection point (16), acting increasing the precision of device regulation . Device according to claim 3, characterized in that said control means is a valve of the guillotine type. Device according to the preceding claims, characterized in that it is provided with a flow regulating device (25), arranged in the conduit (14), between the intermediate point (16) and the inlet of the heat exchanger (3), in order to be able to evacuate the gases outwards in case of emergency. Device according to the preceding claims, characterized in that the draft regulating element (4) is a fan located at the outlet of the heat recuperator (3). Device according to the preceding claims, characterized in that the cogeneration module (1) comprises a gas or diesel turbogenerator whose exhaust gases, at nominal rate, have a temperature between 275 ° C and 650 ° C and an oxygen content between the 15% and 19% by volume. Device according to claims 1 to 5, characterized in that the cogeneration module comprises a motor generator that operates with natural gas or diesel as fuel, the exhaust gases of which have a temperature, at a nominal rate, between 440 ° C and 530 ° C. 9. Device according to the preceding claims, characterized in that it is mounted by modules, forming a compact set for generating cold, electricity and heat.