RU2142608C1 - Recuperation cooler - Google Patents

Abstract

FIELD: refrigerating engineering; systems with air as cooling agent and oil as medium to be cooled. SUBSTANCE: recuperation cooler has at least one section consisting of heat exchange surface and distributing and collecting manifolds for one medium adjoining the surface at opposite sides. Each manifold has operating branch pipes to let in and out medium (oil). Novelty is that each manifold has circulating branch pipe, and entire cooler has at least one bypass line with control shutoff member connected by one end to distributing manifold of one of sections, and by other end, to collecting manifold of one of sections and in case of single-section and in case of single-section cooler, to the same section. Branch pipes communicate through connecting pipelines forming, together with manifolds and bypass lines, a part of closed circuit of preliminary circulation of medium provided with external heat source. EFFECT: enhanced operating reliability at reduced consumption of energy at repeated starting under low temperature conditions of surrounding medium. 9 cl, 10 dwg

Description

 The invention relates to refrigeration, more particularly to regenerative chillers, and in particular to chillers used in such systems in which the refrigerant is air and the medium to be cooled is oil.

 This invention is especially relevant for oil coolers operating in temperate and cold climates.

 Recuperative coolers are known that contain several sections, each of which has a heat exchange surface and distributing and collecting manifolds for one of the media adjacent to it from opposite sides, having respectively working nozzles for entering and leaving the medium (Technical description and installation, operation and maintenance instructions for a group of winter-type oil coolers type 06-10, Budapest, Institute of Energy, 1979, p. 4-9 and drawing 3421-Lk-1).

 In this cooler, all distributing (as well as collecting) collectors are combined by a common distributing (collecting) pipeline, and the heat exchange surface is made tubular, while electric heating elements are introduced into the collectors.

 It is possible to start such a cooler at low ambient temperatures only at high energy costs, since in the specified cooler the collectors are heated by convective heat transfer between the oil heated by the electric heating elements immersed in it and the collector body, the heat-exchanging surface is heated by convective heat transfer between the outer surface of the sections and hot air supplied by autonomous fans through autonomous electric heaters. At the same time, heat losses to the environment are large due to the leakage of the cooler and the absence of insulation on it. Therefore, an increase in operational reliability with a simultaneous decrease in energy consumption when starting the cooler at low ambient temperatures is not achieved.

 Recuperative coolers are also known, containing at least one section consisting of a heat exchange surface and adjacent to it from the opposite sides of the distributing and collecting manifolds for one of the media having, respectively, working nozzles for entering and leaving the medium (Gas Industry, N 1, 1985 , p.22-23).

 However, in this cooler there are no means providing guaranteed warm-up of the heat-exchange sections under starting conditions at low ambient temperatures, which in practice leads to thermal shocks, to a significant increase in the resistance of the oil cavity and, accordingly, the oil pressure due to its sharp cooling when it enters the cold sections; as a result, there are cases of depressurization of sections and their failure. Therefore, the technical result achieved by the invention, the increase in operational reliability while reducing energy consumption when starting the cooler at low ambient temperatures, is not achieved.

 By the number of common features, this object is closest to the invention and adopted as a prototype.

 The objective of the invention is the development of the design of a recuperative cooler, ensuring its reliable operation with a high resource if it is necessary to run it repeatedly in conditions of low ambient temperature.

 The main technical result achieved by the invention is to increase operational reliability while reducing energy consumption during repeated starts in low ambient temperatures.

 An additional technical result achieved by the invention is the intensification of the heating process.

 The main technical result is achieved by the fact that in a recuperative cooler containing at least one section, consisting of a heat exchange surface and adjacent to it from opposite sides of the distributing and collecting manifolds for one of the media, each having respectively working nozzles for entering and leaving the medium, each collector The section additionally contains a circulation pipe, and the entire cooler is equipped with at least one bypass line with a regulating shut-off element connected at one end to the distributing call to the projector of one of the sections, and the other end to the collecting collector of also one of the sections.

 In the particular case, the same technical result is achieved by the fact that one of the bypass lines is connected at one end to the circulation pipe of the collecting manifold, and at the other end to the circulation pipe of the distribution manifold; one of the bypass lines is connected at one end to the circulation pipe of the distribution manifold, and at the other end to the working pipe of the collecting manifold; one of the bypass lines is connected at one end to the circulation pipe of the collecting manifold, and at the other end to the working pipe of the distribution manifold; however, these pipes are communicated by means of connecting pipelines, which together with collectors and bypass lines form part of a closed circuit of the preliminary circulation of the medium having an external heat source.

 An additional technical result is achieved by the fact that the heat transfer surface is made in the form of at least one plate-ribbed package of alternating flat and corrugated sheets; the packages are equipped with flat electric heaters, while a gap is provided between adjacent packages in the section, and the heaters are installed on the outer side walls of the packages and in the indicated gaps.

 The same result in particular cases is also achieved by the fact that at least one of the collectors is equipped with a surface electric heater, profiled in the shape of a collector and mounted on its outer surface; surface electric heaters are made in the form of an electrically conductive element consisting of a non-metallic heating layer enclosed in a polymer shell.

 Figure 1 presents a diagram of a closed loop of the working and preliminary circulation of oil with the described recuperative cooler.

 In FIG. 2 schematically shows a three-section cooler with one bypass line, illustrating p.p. 2 and 3 of the claims.

 In FIG. 3 - the same cooler, also illustrating claims 2 and 3 of the claims.

 Figure 4 schematically shows a two-section cooler with two bypass lines.

 Figure 5 schematically shows a four-section cooler with four bypass lines.

 In FIG. 6 shows a section of a regenerative cooler in a perspective view illustrating the location of surface heaters on the side walls of the bags and on the outer surface of the collectors, working and circulation pipes.

 In FIG. 7 is a perspective view of a plate-fin package of a cooler section.

 Fig. 8 shows a perspective view of a cooler collector with a surface heater profiled in the shape of the collector body.

 In Fig.9 is a section aa of Fig.8.

 Figure 10 is a section aa of figure 6.

 Recuperative cooler design.

 The recuperative cooler comprises at least one section 1 (see FIG. 1). The cooler may contain several sections, in particular, additional sections 2, 3 and 4 (see Fig. 2, 3, 4, 5). Each section has a heat exchange surface 5, distributing 6 and collecting 7 collectors. In turn, the distributing manifold 6 has a working pipe 8 for medium inlet and a circulation pipe 9 collecting collector 7, respectively, a working pipe 10 and circulating 11. The cooler has at least one bypass line 12 with an adjusting shut-off element 13. The cooler may have also several bypass lines, in particular, additionally 14, 15 and 16 (see Fig. 2, 3, 4, 5). The bypass line 12 is connected at one end to the distribution manifold 6 of one of the sections, and the other end to the collecting manifold 7 also of one of the sections. At the same time, the regulating shut-off element can be made in the form of a manually operated gate valve, or in the form of temperature controllers of various designs that automatically change the oil flow through the bypass line from zero to a maximum value depending on the oil temperature.

 The described recuperative cooler (see Fig. 1) is included in the oil cooling system (or other liquid medium prone to thickening or freezing) to the specified operating temperatures with the help of air pumped by fans (not shown). This system contains a pump 17 and a heat source 18 (the source may be bearings of a gas turbine engine, supercharger, compressor, etc.). The pump 17 line 19 (through the source 18) is connected to the working pipe 8 for oil inlet to the distributing manifold 6 and line 20 with the working pipe 10 of the collecting manifold 7 for oil exit.

 When performing a multi-section cooler, it will be included in a similar oil cooler circulation system. The difference will only be in specific pipes to which lines 19 and 20 will be connected.

 This system has a closed loop of the preliminary circulation of the medium, including lines 19 and 20, a source of heat 18, a pump 17, collectors 6, 7 and a bypass line 12.

 The system also has a closed loop of the working medium circulation, including lines 19 and 20, heat source 18, pump 17, heat exchange surface 5, distributing and collecting manifolds 6, 7.

 Similar circuits will be with several bypass lines. In multi-section coolers (see Figs. 2, 3, 4, and 5), at one end of adjacent collectors (either distributing 6 or collecting 7) facing one another, there is a working pipe (either 8 for entering the medium, or 10 - to exit the medium), and at the other end of the adjacent collector - circulation 9 or 11. The working and circulation pipes are connected by connecting piping 21. Piping 21 together with the collectors 6 and 7, and bypass lines 12, 14, 15 and 16 form parts of a closed the contour of the preliminary circulation of the medium having an external heat 18 and pump 17. The same pipelines 21 with the same collectors 6 and 7 together with the heat exchange surface 5 of sections 1, 2, 3, 4 form part of a closed loop of the working medium circulation, having a heat source 18 and pump 17.

 FIG. 1 and 2 illustrate options when the circulation pipes to which the bypass line is connected belong to the same section. In FIG. 3 illustrates the case when the circulation pipe 9 of the distributing collector 6 of section 3 is connected to the circulation pipe 11 of the collecting collector 7 of section 1. A cooler with two bypass lines 12 and 14 is possible (see Fig. 4), where the bypass line 12 connects the circulation pipe 11 the collecting manifold 7 and the working pipe 8 of the distributing collector 6 of section 1, and the bypass line 14 is the circulation pipe 9 of the distributing collector 6 and the working pipe 10 of the collecting collector 7 of section 2. A four-section cooling is also possible a boiler with four bypass lines 12, 14, 15 and 16 (see FIG. 5), where the sections are divided into two parallel groups, each of which consists of two sections.

 Thus, the distributing and collecting manifolds, to the circulation pipes of which the bypass line is connected, are the last distributing collector along the medium in the closed preliminary circulation circuit and either collecting the collector of the same section (see Fig. 2) or collecting collector of the section having the first distributing collector along the medium in a closed loop of the preliminary circulation (see figure 3).

 Sections 1, 2, 3, and 4 may consist of either a single plate-ribbed packet 22, or several packets (see Fig.6). The bags 22 are equipped with surface electric heaters 23, while the heaters are installed both on the outer side walls 26 of the bags 22, and in the gaps 27 provided between the packages of sections. The same heaters 33, but profiled by the shape of the collector can be installed on the collectors 6, 7.

 Surface electric heaters are made in the form of an electrically conductive element, which is a non-metallic heating layer 24, enclosed in a polymer shell 25.

 As shown above, the heat exchange surface 5 is mainly made in the form of a plate-rib package (see Fig. 7) of alternating flat 28 and corrugated 29 sheets forming channels 30 (oil channels) for the medium to be cooled and channels 31 (air channels) for the cooling environment (air).

 In this case, the regenerative cooler is made, as a rule, cross-flow, and on the supply side of the second medium (usually air) has no collectors.

 Embodiments of a recuperative tube cooler or other known type are possible. The material from which the cooler is made must be a metal with high thermal conductivity, for example aluminum, its alloys, etc.

 Recuperative cooler collectors can either be collecting or distributing; in the first case, each collector has a working pipe 10 for medium output, in the second case, a working pipe 8 for medium input.

 The collecting manifold 7, comprising a housing 32 with a working nozzle 10 for outputting the medium, has an additional circulation nozzle 11 connected to a bypass line or connecting pipe. In this case, the working 10 and circulating 11 nozzles are located at opposite ends of the collector 7.

 The collector 7 is equipped with a heater 33, made in the form of an electrically conductive element, profiled in the shape of a collector and mounted on its outer surface (if such a heater is straightened, it will be similar to a surface heater 23). The conductive element (see Figs. 9 and 10) has an insulation layer 34 and power supply wires 35 (see Fig. 6) and is made in the form of a non-metallic heating layer 24, for example, graphite, enclosed in a polymer sheath 25.

 Distributing manifold 6 has the same device as the collecting manifold 7, and is installed on the opposite side of the heat exchange surface 5 (see figure 6).

 The housing 32 of the collectors 6, 7 are made of a material with high thermal conductivity, for example, aluminum.

 A similar heater 33 may also be installed on the lines leading to the collectors.

Recuperative Cooler Operation
The oil heated in bearings (heat source 18) to t = 60-120 ^o C, through a pump 17 through line 19 enters the distributing manifold 6, then to the heat exchange surface 5, where it is cooled to a predetermined temperature, and then to the collecting manifold 7 , from where, through line 20, the cooled oil is returned to the bearings using pump 17 (see figure 1). Cooling air is supplied to the heat exchange surface with the help of fans, by adjusting the performance of which they achieve the desired cooling mode. Depending on the amount of oil and other production and heating conditions, the recuperative cooler can be multi-sectional. In this case (see figure 2, 3, 4, 5), the essence of the work will not change, and the hot oil will be pumped through all the heat transfer surfaces of all sections (sequentially or in parallel) and cooled by the air flow.

 In startup mode, the regenerative cooler operates as follows.

The start mode starts with a non-working gas turbine engine or supercharger, when the oil temperature is 10-15 ^o C, and the temperature of the regenerative cooler (its collectors, heat exchange surface), which is located outdoors, can reach minus 60 ^o C.

 In this mode, the described method involves the operation of preliminary circulation of oil through all distributing and collecting manifolds of all sections (see Fig. 2, 3, 4, 5) bypassing the heat exchange surface or through collecting and distributing manifolds of one section (see Fig. 1) with a single-section cooler, in this case, after completion of the preliminary oil circulation, the latter is fed to the heat exchange surface directly from the distributing sections of the cooler. This operation is carried out using bypass lines with a regulating locking element 13: when performing a single-section cooler using a bypass line 12 (see figure 1), when performing a multi-section cooler using bypass lines 12, 14, 15, 16 (see figure. 2, 3, 4, 5).

 The start mode begins with the supply of heat to the outer surfaces of the sections of the cooler by conductive heating.

 In particular cases, conductive heating begins either by supplying heat directly to the collectors, or to the heat exchange surface of the sections, or to both. At very low ambient temperatures, additional conductive heating is carried out by supplying heat to the pipelines leading to the collectors of the cooler sections.

In other words, the start mode begins with the inclusion of certain heaters, while the circulation circuit is not turned on (engine or supercharger do not work). The surface heating of the cooler sections due to their implementation from materials with high thermal conductivity is carried out intensively, and after some time the condition t _ps will be satisfied = t _m. ± 20 ^o C, where t _p.s. - surface temperature of the cooler sections in degrees Celsius; t _m - oil temperature in degrees Celsius. In practice, this temperature is 10-15 ^o C, and the temperature of the heaters themselves does not exceed 100-130 ^o C.

 After that, they proceed to the preliminary circulation of the oil, which begins simultaneously with starting the engine or supercharger and turning off the heaters 23 and 33. In practice, this operation is carried out as follows. The regulator 13 on all bypass lines 12, 14, 15, 16 is set to the “open” position, the shutters (not shown) are opened on the lines 19, 20, and the oil pumped by the pump 17 through the line 19 and the heat source 18 enters the working the pipe 8 of the distributing collector 6 of section 1 (see FIG. 1) and further, bypassing the heat exchange surface 5 (due to its high hydraulic resistance at low oil temperatures), is sent through the circulation pipe 9 and the bypass line 12 to the circulation pipe 11 of the collecting manifold 7 and through operating pipe 10 of the manifold 20 and line 17 back to the pump.

 In multi-section coolers, the oil in the preliminary circulation circuit bypasses the heat exchange surface 5 either sequentially through all the distributing manifolds 6, the bypass line 12 and then sequentially through all the collecting manifolds 7 (see figures 2 and 3), or it enters simultaneously into the distributing 6 and collecting 7 collectors of one section, then through the same collectors of another section (see Fig. 4 and 5).

 The oil, circulating along the preliminary circulation circuit, including the heat source 18, is gradually heated, while also gradually heating the cooler sections. As the oil temperature rises, the shut-off element 13 begins to close gradually, directing an increasing part of the oil from the distributing manifolds 6 to the heat exchange surface 5. After the oil reaches a temperature equal to approximately its operating value, the regulating shut-off element 13 is completely closed and all the oil from the distributing manifolds 6 sent to the heat exchange surface of 5 sections of the cooler; thereby stops the preliminary circulation of oil, and the operating mode.

At the same time, an option is envisaged in which the preliminary circulation is completed stepwise - first for one group of sections, then for another (see figure 5). This technique is carried out, for example, by setting the regulating locking elements in sections 1, 2 at a temperature of 50 + 10 ^o C, and in sections 3, 4 at a temperature of 60 + 10 ^o C.

 In this case, the work of the collectors is as follows. The operation of the collector is described in a particular embodiment of its use in a recuperative cooler with a plate-fin surface, when the medium to be cooled is oil and the cooling medium is air, and the oil circulates in a closed circuit with a heat source. Since the collector can be distributing, or collecting, the operation of both collectors together is described (see Fig. 1, 8 and 9).

 In the mode of using the collector when starting the recuperative cooler at low ambient temperatures, the heater 33 is turned on. Since the collector bodies 32 are made of material with high thermal conductivity, they quickly heat up. When the temperature of the housing reaches a value close to the temperature of the oil, the latter, when the pump 17 is turned on, is fed into the nozzle 8 of the distribution manifold, while the shut-off element 13 of the bypass line is in the open position, and the heaters 33 are turned off. The oil received in the pipe 8 rushes to the circulation pipe 9, bypassing the heat exchange surface (since the latter has a high hydraulic resistance), then passes through the bypass line 12 and through the circulation pipe 11 enters the collecting manifold 7, from where through the working pipe 10 to the consumer . Thus, the oil will circulate along the reservoirs, increasing the effect of heating them and naturally heating the sections to a predetermined temperature, after which the shut-off element 13 gradually closes, and the reservoirs switch to the operating mode.

 In operating mode, the regenerative cooler operates as follows.

 A variant of the cooler operation is described when the cooled medium (supplied to the collectors) is oil and the cooling medium is air, while the bypass line is connected to the circulation cooling circuit of the bearings of a gas turbine engine or supercharger.

 In operating mode (the regulating shut-off element 13 of the bypass lines 12, 14, 15 and 16 is closed), the oil pumped from the oil tank (not shown in Fig. 1) is pumped through the line 19 to the heat source 18, which are the bearings of a gas turbine engine or a supercharger, through the line 19 . Having lubricated and cooled the bearings and absorbed the heat of friction, the heated oil is sent to the working nozzle 8 for the inlet of the medium of the distributing collector 6 of section 1 of the single-section regenerative cooler (see Fig. 1). From the distributing manifold 6, the heated oil enters the heat exchange surface 5 into the oil channels 30, where it is cooled when cooling air passing through the air channels 31 is pumped by the fans (not shown in the drawings). The cooled oil enters the collecting manifold 7 and through the working pipe 10 to exit the medium and the line 20 (through the oil tank) returns to the suction pipe of the pump 17.

 Variants of the scheme are possible when the heat source 18 is located on the line 20 of the suction line of the pump 17; while the operating mode of cooling the oil remains the same as described above.

 In a multi-section cooler (see Fig. 2), the oil entering the distribution manifold 6 of section 1 is divided into two parts: one part, equal to approximately 1/3 of the total oil flow, enters the heat exchange surface 5 of section 1, and the second part, equal to about 2/3 of the oil flow rate, through the circulation pipe 9 and the connecting pipe 21 enters the working pipe 8 of the distributing manifold 6 of section 2, where, in turn, it is again divided into two parts. Each of these parts is approximately 1/3 of the oil consumption; in this case, one part enters the heat exchange surface 5 of section 2, and the second through the circulation pipe 9 of the distributing collector 6 of section 2 and the connecting pipe 21 into the working pipe 8 of the distributing collector 6 of section 3.

 The oil cooled in section 3, through the collecting manifold 7 of this section, the working pipe 10 for the output of the medium, the connecting pipe 21 and the circulation pipe 11 enters the collecting manifold 7 of section 2, where it is mixed with the oil cooled in section 2, and then through the working the outlet pipe 10 for the medium, the connecting pipe 21 and the circulation pipe 11, the oil enters the collecting manifold 7 of section 1, where it is connected to the oil cooled in section 1, and the total flow rate of the cooled oil through the working pipe 10 of the distributing collector RA 7 section 1 is sent to the highway 20 and then to the pump 17.

 Similarly, multi-section coolers operate in the operating mode, the schemes of which are presented in FIG. 3, 4 and 5. The common will be the serial or parallel passage of oil through the heat exchange surfaces of all sections, bypassing the bypass lines.

 In the operating mode, the heated oil (mainly from the circulation circuit having a heat source) enters the housing 32 of the distribution manifold, and then into the channels 30 of the heat exchange surface, where it is cooled by the air flow passing through the channels 31. The cooled oil enters the housing 32 of the collecting manifold, and then to the consumer. In a particular case, the consumer is a heat source (for example, bearings of a steam or gas turbine).

 During this mode, the heaters 33 are turned off, the regulating shut-off element 13 is closed, and oil does not enter the bypass line 12 through the circulation pipe 9.

 The invention can be widely used in climatic zones with temperate and cold climates where in the cold season thickening and even freezing of oil is possible during the period when the regenerative cooler is not working.

An experimental batch of recuperative coolers designed according to this invention and operating in winter temperatures up to minus 40 ^o C has been manufactured. These coolers passed factory and operational tests that confirmed the high efficiency of oil cooling, as well as an efficient and convenient start of the cooler in cold weather. of the year. The trouble-free life of such coolers is supposed to be equal to 100 thousand hours, but in reality it can be slightly less due to fans and temperature controllers, the warranty period of which can be less than 100 thousand hours. Compared to analog oil coolers the power spent on preheating before starting in the cold season decreased by 10-12 times.

 Currently, mass production of such oil coolers is being mastered.

Claims (9)

 1. A recuperative cooler containing at least one section, consisting of a heat exchange surface and adjacent to it from opposite sides of the distributing and collecting manifolds for one of the media, respectively having working nozzles for entering and leaving the medium, characterized in that each collector sections additionally contains a circulation pipe, and the entire cooler is equipped with at least one bypass line with a regulating shut-off element connected at one end to the distributing manifold of one of the sections, and the other their end towards the collection manifold as one of the sections.  2. The recuperative cooler according to claim 1, characterized in that at one end of the adjacent collectors facing one another, there is a working pipe, and at the other end of the adjacent collector is a circulation pipe, while these pipes are communicated through connecting pipelines forming together with collectors and bypass lines part of a closed loop of the preliminary circulation of the medium having an external heat source.  3. The recuperative cooler according to claim 1, characterized in that the bypass line is connected at one end to a circulating collecting collector and the other to a circulating branch pipe of a distributing collector.  4. The recuperative cooler according to claim 1, characterized in that one of the bypass lines is connected at one end to the circulation pipe of the distributing collector and the other to the working pipe of the collecting manifold.  5. The recuperative cooler according to claim 1, characterized in that one of the bypass lines is connected at one end to the circulation pipe of the collecting manifold and the other to the working pipe of the distributing collector.  6. The recuperative cooler according to claim 1, characterized in that the heat exchange surface is made in the form of at least one plate-fin package of alternating flat and corrugated sheets.  7. The recuperative cooler according to claim 1, characterized in that the packages are equipped with surface electric heaters, while a gap is provided between adjacent packages, and the heaters are installed on the outer side walls of the packages and in said gaps.  8. The recuperative cooler according to claim 1, characterized in that at least one collector is equipped with a surface electric heater, profiled in the shape of the collector and mounted on its outer surface.  9. The recuperative cooler according to claim 1, characterized in that the surface electric heaters are made in the form of an electrically conductive element consisting of a non-metallic heating layer enclosed in a polymer shell.

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