JPS6115341B2 - - Google Patents

Description

[Detailed description of the invention]

The present invention relates to an absorption refrigeration apparatus that uses an absorption refrigeration system to produce a cold/hot heat source by using low potential energy and high potential energy in combination or alone. Heating energy is required to produce a cold/hot heat source, and conventionally, the combustion heat of fossil fuels such as oil and coal and their derivative fuels (heavy oil, city gas),
Alternatively, high-temperature high-potential energy such as high-pressure steam and high-temperature water generated using this combustion heat has been used. However, high potential energy is expensive, and it is desired to suppress the amount of fossil fuel used to prevent fossil fuels from depleting in the future. On the other hand, although low-potential energy such as hot water using solar heat, hot water discharged from factories, and low-pressure steam discharged from steam engines is abundant and inexpensive, it has a low temperature of, for example, 100 degrees Celsius or less. Also, because it is difficult to consistently obtain the required amount, it is not used and conventionally was wasted into the environment. However, in order to effectively utilize the low potential energy of levers, there are facilities that use absorption refrigeration systems to produce cold and hot water, but the temperature of the low potential energy used is low to begin with, and, for example, when using solar heat, If so, the temperature at which the heat is collected may drop due to seasonal changes or changes in the weather, regardless of the usage conditions on the load side, making it difficult to use low potential energy effectively at low temperatures. It was hot. The present invention separates a low-potential generator that heats with low-potential energy from a low-potential condenser that condenses the refrigerant vapor generated therein, and controls the temperature of the cooling medium passed through the low-potential condenser so that it does not cool other parts. By lowering the temperature of the medium, it is possible to eliminate the above-mentioned drawbacks of the conventional ones, reduce the pressure in the low-potential generator, lower the boiling point, and effectively utilize the low-temperature low-potential energy. The purpose of this invention is to provide an absorption refrigeration device. The present invention provides an absorber, a low temperature generator, a high temperature generator,
It is equipped with a condenser, an evaporator, a low-temperature solution heat exchanger, a high-temperature solution heat exchanger, a solution pump, a refrigerant pump, and a solution flow path and refrigerant flow path that connect these devices, and uses low-potential energy and high-potential energy as a heat source. In the absorption refrigerating apparatus, the low-temperature generator has at least a low-potential low-temperature generator heated by low-potential energy, and the condenser is configured to absorb refrigerant vapor generated in the low-potential low-temperature generator. a low-potential condenser for introducing and condensing a refrigerant fluid; and a high-potential condenser for introducing and condensing a refrigerant fluid heated and generated by high-potential energy in at least the high-temperature generator; A cooling mechanism is provided for cooling and condensing the refrigerant by passing a cooling medium through the cooling mechanism and the high potential condenser, respectively, and the cooling medium guided to the cooling mechanism of the low potential condenser is lower than the cooling medium guided to the cooling mechanism of the high potential condenser. It is also an absorption refrigeration system characterized by its low temperature. The present invention will be described with reference to the drawings in accordance with embodiments. As shown in FIG. A condenser C ₁ , a high potential condenser C ₂ , a low temperature solution heat exchanger HEL, and a high temperature solution heat exchanger HEH are provided, and a solution flow path and a refrigerant flow path are provided to connect these devices. As a solution flow path, a low concentration ξ ₁ solution flow path includes a low temperature side solution pump SPL, pipes 1, 2, and 3 connect the absorber A and the low potential low temperature generator GL1,
Medium concentration ξ High temperature side solution pump as ₂ solution flow paths
SPH, pipes 4 and 5 are low-potential low-temperature generators
GL1 and high temperature generator GH are connected, medium concentration ξ ₃ pipes 6 and 7 are used as return solution flow path, high temperature generator GH is connected to high potential low temperature generator GL2, and high concentration ξ ₄ pipes are used as return solution flow path. Lines 8 and 9 connect high potential low temperature generator GL2 and absorber A. The refrigerant flow path includes a refrigerant pump RP and pipes 10 and 11 for circulating the refrigerant in the evaporator E and evaporating it in the cold water pipe 16.
The refrigerant vapor generated in the GH or the refrigerant liquid that is condensed on the way is used as a high-potential low-temperature generator.
The liquid and gaseous refrigerant after exiting the pipe line 12 and the heating pipe 17 are guided to the heating pipe 17 of GL2 to have a double-effect action, and the liquid and gaseous refrigerant are transferred to a high potential condenser _C2.
It is provided with a conduit 13 leading to. Further, a pipe line 14 is provided which leads the refrigerant liquid obtained in the high potential condenser _C2 to the low potential condenser _C1 , and a pipe line 14 leads the refrigerant liquid obtained in the low potential condenser _C1 to the evaporator E.
A conduit 15 leading to is provided. 18 and 19 are cooling pipes for condensation, and pipe line 2
0, 21, and 22 cause a cooling medium such as cooling water to flow. Cooling pipe 18 of low potential condenser C ₁
is located upstream of the cooling pipe 19 of the high potential condenser C ₂ in terms of the flow of the cooling medium, and therefore the cooling water at a lower temperature than in the cooling pipe 19 passes therethrough. 29 is a cooling pipe within the absorber A. 23 is a heating tube as a low-potential heating mechanism in which a low-potential energy heat medium fluid such as hot water using solar heat, waste hot water from a factory, or low-pressure steam discharged from a steam engine is guided to heat the solution. 24 is a flow control valve that controls the amount of heating. A fuel pipe 25, a flow rate control valve 26, a burner 27, and a furnace cylinder 28 are provided as a high-potential heating mechanism using high-potential energy, and a fuel such as city gas or kerosene is combusted to perform high-temperature heating. The solution cycle during operation is shown in Figure 2 as a logP-T graph. Since the coolant temperature in the cooling pipe 18 is lower than that in the cooling pipe 19, the low potential condenser C ₁
The condenser temperature and saturated vapor pressure in the high potential condenser _C2 are lower than the condensing temperature and saturated vapor pressure in the high potential condenser C2. Therefore, the vapor pressure PL1 in the low-potential low-temperature generator GL1 in FIG. 2 is lower than the vapor pressure PL2 in the high-potential low-temperature generator GL2,
Therefore, the evaporation temperature is also lower inside the former. On the other hand, the lower the concentration, the lower the boiling point of the solution. Therefore, boiling can be carried out at the lowest boiling point by supplying the lowest concentration _ξ1 solution derived from the low potential low temperature generator GL1 and absorber A, which have the lowest vapor pressure. That is, the solution can be condensed even at low temperature and low potential energy. The solution then undergoes a dual effect absorption refrigeration cycle with a high potential auxiliary heat source in a high temperature generator GH and a high potential low temperature generator GL2. Therefore, control is performed so that low potential energy is preferentially used as a heat source, and the deficiency is compensated for by high potential energy. For example, the flow control valves 24 and 26
When controlling the flow rate control valve 24, the flow rate control valve 26 does not open until the opening degree of the flow rate control valve 24 reaches the maximum value, and the flow rate control valve 26 does not open until the flow rate control valve 24 reaches the maximum opening degree and the heat source is insufficient. to compensate for high potential energy. Note that the pipe 30 and valve 3 connecting the pipe 4 and the pipe 8
1, and if only low potential energy is sufficient, pour the solution into this connecting pipe 30,
It can also be sent to absorber A to create a single-effect cycle. Since the present embodiment is constructed and operates as described above, low-temperature low-potential energy can be effectively utilized, and consumption of high-potential energy can be reduced. Furthermore, as mentioned above, since the vapor pressure PL1 can be made lower than PL2, the temperature of the refrigerant liquid returned to the evaporator E can be lowered by making the final passage of the refrigerant cycle the low potential condenser _C1 . Therefore, efficiency can be improved by increasing the refrigerating capacity per unit weight of refrigerant circulation. Further, the temperature of the low potential energy can be slightly higher than the low concentration solution outlet (point in FIG. 2) temperature of the low temperature solution heat exchanger HEL. In this case, the low potential energy can be used as a preheat for the absorption solution cycle even though the amount of heat or temperature of the low potential energy is low enough to barely heat up to a point. If it can be used to a point state or higher, it can be used as a single-effect cycle. The lower the vapor pressure PL1 is, the lower the temperature of the low-concentration solution that determines the point state can be lowered, so it is preferable to pass cooling water as low as possible through the cooling pipe 18 of the low-potential condenser _C1 . The absorber A is also equipped with a cooling pipe 29, and a common cooling medium can be used for this. Even in that case, it is preferable to always pass the cooling medium through the low potential condenser _C1 first, so the following combinations of cooling medium flow orders are used.

[Table] The present invention includes an absorber, a low-temperature generator, a high-temperature generator,
It is equipped with a condenser, an evaporator, a low-temperature solution heat exchanger, a high-temperature solution heat exchanger, a solution pump, a refrigerant pump, and a solution flow path and a refrigerant flow path that connect these devices, and uses low-potential energy and high-potential energy as a heat source. In the absorption refrigerating apparatus, the low-temperature generator has at least a low-potential low-temperature generator heated by low-potential energy, and the condenser is configured to absorb refrigerant vapor generated in the low-potential low-temperature generator. a low-potential condenser for introducing and condensing a refrigerant fluid, and a high-potential condenser for introducing and condensing a refrigerant fluid heated and generated by high-potential energy in at least the high-temperature generator;
A cooling mechanism is provided for cooling and condensing the refrigerant by passing a cooling medium through the low-potential condenser and the high-potential condenser, respectively, and the cooling medium guided to the cooling mechanism of the low-potential condenser is guided to the cooling mechanism of the high-potential condenser. Because the temperature is lower than that of the cooling medium used, low-temperature low-potential energy can be used effectively, expanding its range of use, reducing the consumption of precious and expensive high-potential energy, and producing highly efficient, high-performance products. It is possible to provide an absorption refrigeration device, which has extremely great practical effects.

[Brief explanation of the drawing]

FIG. 1 is a flow diagram of an embodiment of the present invention, and FIG. 2 is a solution cycle diagram thereof. A...Absorber, E...Evaporator, GH...High temperature generator, GL1...Low potential low temperature generator, GL
2... High potential low temperature generator, C ₁ ... Low potential condenser, C ₂ ... High potential condenser, SPH... High temperature side solution pump, SPL... Low temperature side solution pump, RP... Refrigerant pump, HEH ...High temperature solution heat exchanger, HEL...Low temperature solution heat exchanger,
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 1
1, 12, 13, 14, 15... pipe, 16...
Cold water pipe, 17... Heating pipe, 18, 19... Cooling pipe, 20, 21, 22... Pipe line, 23... Heating pipe, 24... Flow rate control valve, 25... Fuel pipe, 26
...flow control valve, 27 ... burner, 28 ... furnace tube, 29 ... cooling pipe, 30 ... piping, 31 ...
valve.

Claims (1)

[Claims] 1. Absorber, low temperature generator, high temperature generator, condenser,
Evaporator, low temperature solution heat exchanger, high temperature solution heat exchanger,
Even in absorption refrigeration equipment that is equipped with a solution pump, a refrigerant pump, and a solution flow path and a refrigerant flow path that connect these devices, and uses low potential energy and high potential energy as a heat source,
The low-temperature generator has at least a low-potential low-temperature generator heated by low-potential energy, and the condenser is a low-potential condenser that introduces and condenses refrigerant vapor generated in the low-potential low-temperature generator. and a high-potential condenser for introducing and condensing a refrigerant fluid heated and generated by high-potential energy in at least the high-temperature generator, and cooling the low-potential condenser and the high-potential condenser, respectively. An absorption absorber comprising a cooling mechanism for cooling and condensing a refrigerant through a medium, wherein the cooling medium guided to the cooling mechanism of the low potential condenser has a lower temperature than the cooling medium guided to the cooling mechanism of the high potential condenser. Refrigeration equipment. 2. The apparatus according to claim 1, wherein the cooling medium that has passed through the cooling mechanism of the low potential condenser passes through the cooling mechanism of the high potential condenser downstream thereof. 3. The device according to claim 1 or 2, which is configured to guide the refrigerant liquid condensed in the high potential condenser to the low potential condenser. 4. Claim 1, wherein the absorber is provided with a cooling mechanism, and the cooling medium that has passed through the cooling mechanism of the low-potential condenser passes through the cooling mechanism of the absorber downstream thereof.
2. The device according to item 2, item 3, or item 3. 5. The absorber is provided with a cooling mechanism, and the cooling medium that has passed through the low-potential condenser cooling mechanism and then the high-potential condenser cooling mechanism passes through the absorber cooling mechanism downstream thereof. Claim 1 constructed as follows:
3. The device according to item 2, item 3, or item 4. 6. The low-temperature generator has a high-potential low-temperature generator equipped with a heating mechanism that heats a solution by guiding refrigerant vapor generated by high-potential energy in the high-temperature generator or a condenser of the refrigerant vapor, and 6. A device according to any one of claims 1 to 5, in which a dual-effect cycle of energy is formed.