RU2076285C1 - Reverse cycle at two boiling points and refrigerating machine - Google Patents

Abstract

FIELD: refrigerating engineering. SUBSTANCE: refrigerating machine has two independent closed low-pressure and high-pressure loops of compressor provided with two suction branch pipes of different pressures and two delivery branch pipes. Low-pressure loop is formed by compressor delivery branch pipe, condenser, low-pressure control valve and low-pressure compressor suction branch pipe connected in series. High-pressure loop is formed by delivery branch pipe, condenser, high-pressure control valve, high-pressure evaporator and high-pressure compressor suction branch pipe. Compressor may be of vortex type; additional delivery branch pipe is located in area of splitter of compressor working chamber. EFFECT: enhanced efficiency. 4 cl, 1 dwg

Description

 The invention relates to refrigeration machine and compressor engineering and may find application in the compression of the vapor phase of the working fluid in other areas of technology.

 In refrigeration technology, a reverse cycle is realized, implemented by a single-stage refrigeration machine. The main advantage of such a cycle and machine is the extreme simplicity of producing artificial cold (Thermophysical basis for producing artificial cold. Handbook. M. Pishchepromizdat, 1980, p. 232).

 A somewhat complicated construction of a single-stage compression compressor (piston or screw) with a device for recharging refrigerant vapor into the working cavity of the compressor is also known, which allows one to achieve the advantages of two-stage compression with a relatively simple compressor with one stage, i.e. to increase both the degree of reversibility of the workflow and reduce throttling losses by replacing a single cross-linking of the agent with a double one (Tsydzik V.I. et al. Refrigeration machines and apparatuses. M. Mashgiz, 1946, p. 672).

 In recent years, the so-called vortex compressors have gained great popularity in the compression and transportation of gases, which have many advantages in comparison with traditional types of compressors: simplicity of the device, high pressure, high reliability, insensitivity to surging, low cost of manufacture and operation, low maintenance, etc. With the economics of compression, roughly comparable to small reciprocating machines, vortex compressors significantly outperform them in terms of manufacturability, to structural simplicity and reliability in operation, which is primarily confirmed by their use in systems of nuclear power plants, where, as you know, the requirements for failure-free operation are very high (IM Virshubsky et al. Vortex compressors. L. Mechanical Engineering, 1988, p. 272).

 In connection with this application, it is necessary to especially emphasize, as follows from the cited source, the relatively low efficiency of these machines under gas compression and the possibility of increasing their pressure while ensuring recirculation of the working fluid in a certain part of the working chamber of the stage (ed. St. USSR N 1090923, cl. F 04 D 17/06; N 1467253, CL F 04 D 17/06).

The low efficiency of vortex compressors is due, in particular, to the following organic disadvantages of these machines:
the flow of hot vapors through the shut-off from the discharge side to the suction side and the associated significant increase in suction temperature at the inlet to the stage, as well as significant due to the expansion of compressed hot vapors and an increase in suction temperature, a decrease in the stage capacity;
the presence of ballast circulation of the superheated working fluid in the interscapular channels of the vortex wheels, which in turn further increases the temperature of the body at the entrance of the stage, which further reduces the performance of the stage;
deterioration as the flow structure moves in the working chamber as a result of a decrease in the volume of the compressible body with a constant geometric volume of the toroidal cavity of the chamber.

 Therefore, it is obvious that the elimination or reduction of the negative impact of these shortcomings can radically increase the efficiency of the process of compression of the vortex steps. But fundamentally new in terms of increasing the efficiency of the compression process should be considered not only the elimination (almost complete) of the first two drawbacks, but also their transformation into a useful stream to generate a virtually free “superplan” cold by organizing an additional reverse cycle and implementing its refrigeration circuit based on application of a single-stage vortex compressor according to ed. St. N 1467253. At the same time, the negative effect of the third drawback is greatly smoothed out due to the stage recharging during compression with an additional amount of the working fluid, which, in addition to ensuring recirculation, also leads to a decrease in the flow diffusivity in the end part of the stage (in the area after recharging), having a positive effect the efficiency of the vortex stage as a whole.

 Further, regarding the advantages of using vortex compressors for performing a steam reverse cycle with recharging, it can be argued that due to the inherent features of the flow of the working process and the claimed technical solution in this application, they promise lower energy consumption than when compressing gases, as a result of saving the compression work, caused by lowering the temperature of the working fluid due to the mixing of vapors of different thermodynamic states during recharging, and as a result of eliminating the influx of hot vapors ek and ballast to the suction side, eventually causing a significant reduction in compression discharge temperature and therefore a substantial increase in the efficiency of vortex stage.

 In light of the foregoing, the new reverse cycle and the first time a refrigeration machine with an unconventional single-stage vortex compressor is first proposed for its implementation is obviously the most advanced scientific and technical proposal to improve the efficiency of refrigeration machines today.

 The closest prototypes in gas compressor engineering are vortex compressor samples with a suction of hot gases from the cut-off device (ed. St. N 1467253, class F 04 D 17/06) and with recharging into the working chamber of the stage (aut. St. N 332321, class F 04 D 17/18; N 1090923, CL F 04 D 17/06).

 The purpose of the invention is a significant increase in efficiency with an overall increase in the productivity and pressure of the vortex stage, as well as obtaining a second boiling point and a significant expansion of the ability to control flow and pressure characteristics during the production of artificial cold due to the introduction of a paired reverse cycle, combining two separate cycles in joint compression in a single-stage compressor , and implementing its dual-circuit refrigeration machine.

 This goal is achieved by the fact that in the circuit of the chiller that carries out the main cycle, a vortex compressor is used, equipped with at least two additional nozzles, one for taking hot vapors in the section of the cutter, and the other for supplying cold vapors to the cavity, so that it is possible to realize the second, in parallel acting reverse cycle, which differs from the first (main) in the general case by lower productivity and increased condensation and boiling temperatures, which, practically eliminating the inherent vortex Serious flaws associated with steam overflows from the suction side and the inevitable ballast circulation essentially turn this separate and significant harmful total flow into a new source of additional cold with the possibility of using this “free” cold to improve thermodynamic, energy and volumetric parameters of the main cycle, and for generating consumer cold at a second boiling point, which in general will dramatically increase the efficiency of the proposed new cycles vortex compressor and shoe.

 Of particular importance in terms of designating new qualities and previously unknown significant features of the invention is the new property of the proposed system, such as the possibility of its operation at zero flow rate in the main circuit (the discharge valve is closed), when the cold is generated by the implementation of an additional cycle in the second refrigeration circuit, t .e. entirely due to the flow of the cutoff with a higher pressure removed from the zone. This will undoubtedly sharply increase the degree of step pressure increase, as it is known that at zero flow rate, the pressure in the cavity of the working chamber increases several times. Another qualitative transformation is taking place, the claimed cycle and the machine with the compressor of one-stage compression become a two-stage compression system. Moreover, such a transition does not require any structural changes or re-equipment, but is carried out at the level of simple regulation, indicating the unprecedentedly wide and flexible capabilities of the latter compared to traditional methods of changing the flow and pressure characteristics of dynamic machines.

 In FIG. Figure 2 shows the Lazarev paired reverse cycle, consisting of the main single-stage cycle 1-2-3-4 and the additional single-stage cycle 5-6-7-8, realized by a converter of a significant total harmful flow rate (overflow of hot vapors from injection to suction and ballast circulation of hot vapors in the interscapular channels of the impeller) into a useful source of generating virtually free cold at a different temperature level, while at the same time eliminating almost all the negative effects on economic awn workflow two kinds of typical steps for eddy losses. A characteristic feature of the implementation of a paired cycle is the joint compression of two (main and additional) flows during separate flow of known isothermal processes of boiling and condensation, as well as double refrigerant throttling. The area hatched in the state diagram of lgP-i characterizes the savings in compression work in the proposed cycle. At the same time, the possibility of complete intermediate cooling due to only "free" cold, i.e. without the use of a water cooler, which cannot be dispensed with in a conventional circuit with intermediate pressure.

 Figure 1 presents a schematic diagram of a double-circuit refrigeration machine Lazarev for the implementation of the above new cycle.

 The proposed shoe consists of a vortex compressor 1 with a pipe 2 for additional steam supply to the working chamber of the vortex stage and an additional pipe 3 for the removal of hot vapors from the shut-off device, condenser 4, evaporator 5 and regentile 6 (PB 1) of the main circuit, as well as condenser 7, evaporator 8 and regventile 9 (PB 2) of the additional circuit of the machine.

 The specifics of the operation of the vortex stage allows introducing into the working chamber an additional amount of the working fluid at a certain intermediate pressure depending on the location of such a nozzle, bearing in mind that the magnitude of this pressure increases along the length of the chamber in the direction from suction to discharge. Therefore, the proposed single-stage vortex compressor with additional nozzles 2 (for recharging) and 3 (for venting hot vapors) will be able to realize two separately proceeding reverse cycles with joint compression of separate flows of these cycles paired together in the working stage.

 Paired reverse cycle and the operation of the described hill with a single-stage vortex compressor and two refrigeration circuits is as follows.

 The cold steam formed in the evaporator 5 of the main circuit after throttling by the valve 6 is sucked off by the compressor 1 through the suction pipe and then pumped into the condenser 4 of the main circuit, after which the liquid flows to regentile 6, as in a conventional single-stage refrigeration machine. At the same time, hot pairs of leaks and ballast circulation from the cutter through the pipe 3 are pumped into the condenser 7 of the additional circuit, and the condensed liquid, throttled by the valve 9, enters the evaporator 8 of the additional circuit, from where the cold vapor is sucked out through the additional pipe 2, designed to recharge the stage, compressor 1. Thus, the additional circuit also operates in the mode of a single-stage hill.

 In other words, one stage of the vortex compressor serves, as it were, two independent single-stage chillers of various capacities, one of which (the smaller one) transforms the volumetric losses usual for vortex machines into useful free cold with a second boiling point. This reduces the work of compression in the main cycle of another machine (greater productivity), which is actually the first circuit of the proposed refrigeration machine. The decrease in compression work is associated with a decrease in the suction and discharge temperatures after mixing vapors of a different state during recharging. Moreover, there are advantages of a cycle with intermediate pressure and double throttling, which reduces irreversible throttle losses in the cycle.

 Lowering the discharge temperature leads to an increase in the efficiency of the vortex stage, operating in the mode of a steam chiller. At the same time, when recharging, the stage pressure increases as a result of the so-called recirculation, which improves the flow structure and reduces the diffusivity of the stream in its end part by adding an additional amount of steam to the stage, which also contributes to an increase in the efficiency of the working process.

 Thus, the newly declared and previously unknown paired reverse cycle and the two-circuit hill implement that implements it on the basis of an unconventional single-stage vortex compressor with additional nozzles for charging and taking refrigerant vapor allow not only to completely eliminate large volume losses of vortex steps, but also turn them into an additional source of free cold with a new boiling point with a general increase in productivity and pressure, and also opens up unprecedented opportunities for reg evidence of productivity and pressure up to the transformation of a single-stage refrigeration system into a high-pressure two-stage.

Claims (4)

 1. The reverse cycle at two boiling points, including compression of the refrigerant, condensation, throttling and evaporation, characterized in that they implement the main cycle containing compression of the refrigerant stream to a relatively low pressure, condensation, throttling and evaporation under reduced pressure, and an additional cycle, comprising compressing a portion of the stream to a relatively high pressure, condensation, throttling and evaporation at elevated pressure.  2. A refrigeration machine containing a compressor with two suction nozzles of different pressures and a discharge nozzle connected to the working chamber, a condenser, control valves of different pressures, characterized in that it includes two autonomous closed circuits of relatively low and high pressures and an additional condenser, the compressor is equipped with an additional a discharge pipe, wherein the relatively low pressure circuit is formed by a series-connected compressor discharge pipe, condens the compressor, the low pressure control valve, the low pressure evaporator and the suction pipe of the low pressure compressor, and the relatively high pressure circuit with the additional discharge pipe of the compressor, the additional condenser, the high pressure control valve, the high pressure evaporator and the suction pipe of the high pressure compressor.  3. The machine according to claim 2, characterized in that the compressor is made of a vortex type, with an additional discharge pipe located in the region of the cutter of the working chamber of the compressor.  4. The machine according to claim 3, characterized in that the compressor is equipped with at least two discharge pipes of the high pressure compressor located along the length of the working chamber between the suction pipe of the low pressure compressor and the discharge pipe of high pressure.

Images