RU2044970C1 - Thermal converter unit - Google Patents

Abstract

FIELD: heat engineering, refrigerating engineering, absorption machines, thermal converter units and other apparatus of identical purpose. SUBSTANCE: thermal converter unit has desorber 1, absorber 2, evaporator 3, their sprinklers 4, 5 and 6, condenser 7 and solution recuperative heat exchanger 8 arranged in common housing 9 and connected with media being heated and cooled from consumer sources 22, 24 and 26 by means of lines 21, 23 and 25. Heat exchanger 8 is arranged in chamber 12 between desorber 1 located above it and condenser 7 mounted in horizontal row together with it, as well as between absorber 2 located under it and evaporator 3 mounted in horizontal row together with it. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to heat engineering and can be used in refrigeration, absorption machines, heat converting plants and other devices of a similar purpose.

 Heat-converting units are known, containing a stripper, a condenser, an absorber, an evaporator and a heat exchanger of solutions, respectively connected to lines with heated and cooled media.

 The disadvantages of the known heat-converting plants include the possibility of increasing productivity only through the use of more plants of the same capacity or increasing the number of modifications in terms of productivity, which is inefficient.

 Closest to the technical nature of the invention is an installation comprising a module with a stripper, condenser, adsorber, evaporator, sprinklers and heat exchanger solutions enclosed in a common housing, respectively connected to lines with heated and cooled media.

 This installation is selected as a prototype.

In addition to the above disadvantages of the installation should be attributed
the need to organize individual external channels for the passage of the vaporous working substance from the stripper to the condenser and from the evaporator to the absorber, which leads to a significant increase in size and material consumption;
increased power of circulation pumps due to excessive module height;
vertical layout in the module of devices one above the other leads to an increase in material consumption.

 The main objective of the development is the creation of such a multifunctional heat-converting installation in which its devices would be arranged in a single module with the highest degree of efficiency of using low-grade heat with less metal consumption.

 The purpose of the invention is improving reliability and efficiency.

 To solve this problem and achieve the goal in a heat recovery plant containing a stripper, absorber, evaporator, sprinklers, condenser and a regenerative heat exchanger of absorbent solutions, enclosed in a common housing, respectively connected to lines with heated and cooled media, its regenerative heat exchanger of absorber solutions is placed between in pairs vertically mounted, arranged in a horizontal row and separated by partitions by a stripper with a condenser above it and an absorber m with an evaporator underneath it, hermetically fastened to the common casing, connected directly to the stripper cavity through the inlet to the annulus, and connected to the absorber sprinkler, the outlet from its pipe space is made in the wall of the heat exchanger or common casing and connected to the stripper sprinkler, and the input to it the tube space is made in the wall of the common housing and is connected to the intake line of the liquid absorber from the absorber, the partition between the stripper and the condenser is fastened to the common housing and the heat exchanger, and between the absorber and ispa with a common housing, both partitions are made with passages for the vaporous medium from the stripper to the condenser and from the evaporator to the absorber, the cavity of the condenser is connected via a liquid absorbent with a line to the evaporator sprinkler, the tube spaces of the absorber and condenser are connected in series with the line to the source of the consumer of the heated medium.

Distinctive features of the heat conversion plant are as follows:
placing a recuperative heat exchanger between a pair of vertically installed, located in a horizontal row and separated by partitions with a desorber with a condenser above it and an absorber with an evaporator under it;
tight fastening of the heat exchanger with a common housing;
the connection of its input into the annular space directly with the cavity of the stripper;
the connection of its output from the annular space with the absorber sprinkler;
the conclusion from its pipe space in its wall or in the wall of the common housing;
the connection of the specified output with the sprinkler desorber;
the introduction into the tube space of the heat exchanger in the wall of the common housing;
connecting said input to a line for collecting a liquid adsorbent from an absorber;
fastening the partition between the stripper and the condenser with a common housing and a heat exchanger;
fastening the partition between the stripper and the evaporator with a common body;
the execution of both partitions with passages for the vaporous medium from the stripper to the condenser and from the evaporator to the absorber;
the connection of the cavity of the condenser along the liquid absorbent line with the sprinkler of the evaporator;
serial connection of the tube spaces of the absorber and the condenser by a line with the consumer's source of the heated medium.

 These distinctive features are significant, since their exclusion from the total set of features does not allow us to solve the problem and achieve a new positive effect. For example, the exclusion of a cavity between vertically mounted rows of a stripper with a condenser and an absorber with an evaporator leads the development to its initial position before the change, which does not allow to obtain advantages.

 Distinctive essential features are new, since their use in known solutions was not found, which allows us to characterize the proposed technical solution in comparison with analogues and prototype corresponding to the criterion of "novelty."

 A single set of common known and new significant features in the proposed technical solution allows to use it to solve the problem and achieve a new positive effect, expressed in reducing heat loss and increasing reliability, which allows it to be characterized by significant differences compared with the prior art, analogues and prototype. Well-known design decisions, standards and recommendations were not used in the development of the heat-converting installation, the development was obtained as a result of research and experimental work, creative contribution, which indicates the compliance of the proposed technical solution with the criterion of "inventive step".

 The invention is illustrated in the drawing, which shows a structural diagram of the proposed installation.

 The heat-converting installation contains a stripper 1, an absorber 2, an evaporator 3, their sprinklers 4, 5 and 6, respectively, a condenser 7 and a regenerative heat exchanger 8 of absorbent solutions, enclosed in a common housing 9 so that the heat exchanger 8 is located between the stripper 1 and installed with it him in a horizontal row with a condenser 7 and an absorber 2 located below it and an evaporator 3 installed with it in a horizontal row.

 Thus, in the common casing 9 there are five cavities 10, 11, 12, 13, 14 for placement of a stripper 1, a condenser 7, a heat exchanger 8, an absorber 2 and an evaporator 3, respectively. The cavities 10, 11, 13 and 14 are separated by partitions 15 and 16. The partition 15 between the stripper 1 and the condenser 7 is bonded to a common housing 9 and a heat exchanger 8, and the partition 16 between the absorber 2 and the evaporator 3 only with a common housing 9. The input 17 into the pipe space of the regenerative heat exchanger 8 is made in the wall of the common housing 9, and the output from it is connected by line 18 to the sprinkler 4 desor bera 1 passing through the wall of the heat exchanger 8 or the wall of the common housing.

 The input 19 into the annular space of the heat exchanger 8 is directly connected to the cavity 10 of the stripper 1, and the output with the sprinkler 5 of the absorber 2, and the cavity 11 of the condenser 7 is connected via a liquid absorbent line 20 to the sprinkler 6 of the evaporator 3.

 The housing 9 is a shell with end boards, internal partitions and pipes for supplying and discharging a solution of absorbent and working substance.

 Desorber 1, absorber 2 and evaporator 3 are irrigation type heat exchangers.

 The desorber 1 is connected via an in-tube space with a line to a source consumer 22 of a cooled medium, and through an annular space with an annular space of a condenser 7.

 The absorber 2 through the annular space is connected to the annular space of the evaporator 3.

 The evaporator 3 through the pipe space is connected by a line 23 to the source consumer 24 of the cooled medium.

 The condenser 7 is a heat exchanger, the surface of which is formed by heat exchange tubes. The adsorber 2 and the capacitor 7 along the in-tube space are connected in series by a line 25 to the source consumer 26 of the heated medium.

 The heat exchanger 8 of the adsorbent solutions is a counterflow recuperative heat exchanger of a flooded type, the surface of which is formed by heat exchange tubes, inside which a weak cold absorbent solution flows, and a strong hot absorbent solution circulates in the annulus.

 Desorber 1, condenser 7, absorber 2 and evaporator 3 have removable bundles of heat transfer tubes.

 Heat conversion unit operates as follows.

 In the annulus of desorber 1, absorber 2, in the tube and annular spaces of the heat exchanger 8, the absorbent solution circulates through the heat exchanger 8 to the heat exchanger bundle of the absorber 1. The absorber solution is fed from the absorber 1 through the annulus 1 to irrigate the heat exchanger beam of the absorber 2.

 In the stripper 1, the absorbent boils due to heat from an external source 22. Vapors of the working substance evaporated from the absorbent solution from the stripper 1 are sent to the condenser 7, where they condense on the heat exchange beam due to heat removal to the external consumer 26. The condensate of the working substance flows to the heat exchange beam of the evaporator 3, where it boils off due to the heat of an external source 24. Vapors are sent to the absorber 2, where they are absorbed by a solution of absorbent coming by gravity from stripper 1. The diluted absorbent solution is pumped again pump 27 into stripper 1, and the cycle repeats.

 In the heat exchanger 8 of the absorbent solutions, regenerative heat exchange is carried out between the diluted cold absorbent solution coming from the absorber 2 into the tube space and the concentrated hot solution coming from the stripper 1 into the annular space.

 Thus, the cooling or heating, for example, of the water coming from the consumer, is due to heat from external sources. This is ensured by heat and mass transfer processes between the absorbent solution and the working substance, proceeding in the heat-converting apparatus functionally interconnected.

 The above-described constructive implementation of the installation allows to reduce hydraulic losses by reducing the path of the concentrated absorbent solution from stripper 1 to absorber 2 and solve the problem of ensuring strength from the action of the pressure difference in the cavities 10, 11, and 13, 14 by transferring this load to the heat exchanger 8 of the absorbent solutions .

 A positive effect of using the proposed technical solution in a heat-converting installation is to reduce material consumption by saving material from placing the heat exchanger 8 in the intermediate cavity 12 between the stripper 1, the condenser 7 and the absorber with the evaporator 3, i.e. layout of all installation nodes in a single module.

 Testing a full-scale sample of a heat-converting installation under conditions close to operational, showed its effectiveness and expediency for industrial applications.

 Based on the foregoing, we can conclude that the proposed technical solution meets the criterion of "industrial applicability".

Claims (1)

 HEAT TRANSFORMER INSTALLATION, comprising a stripper, absorber, evaporator, sprinklers, condenser and a regenerative heat exchanger of absorbent solutions, enclosed in a common housing, respectively connected to lines with heated and cooled media, characterized in that its regenerative heat exchanger of absorbent solutions is placed between vertically mounted pairs in a horizontal row and separated by partitions with a stripper with a condenser above it and an absorber with an evaporator under it, hermetically sealed captivity with a common casing, connected by an input into the annular space directly with the cavity of the stripper, and the output with the sprinkler of the absorber, the output from its pipe space is made in the wall of the heat exchanger or common casing and connected to the sprinkler of the stripper, and the input into its pipe space is made in the wall of the common casing and connected to the intake line of the liquid absorbent from the absorber, the partition between the stripper and the condenser is bonded to a common housing and a heat exchanger, and between the absorber and the evaporator with a common housing, both ki formed with passages for the vaporized medium from the stripper to the condenser and from the evaporator to the absorber, condenser cavity by the liquid absorbent from the sprinkler line is connected to the evaporator, the absorber tube space and a capacitor connected in series with the source-line consumer heated medium.