RU2224914C2 - Fan-heat exchanger (modifications) - Google Patents

Abstract

FIELD: ventilation and air-conditioning systems, in which the heat-transfer agents are not mixed with one another. SUBSTANCE: according to the first modification, the device has a body and a two-sided impeller installed in it in the form of a separating disk, the blades of the centrifugal fan are made on the one side of the disk, and those of the centripetal fan- on the other one, which provides a counter flow heat exchange going on through the blades and the disk. The construction permits manufacture of blades of the preset curvature, in particular, such one, which ensures a constant width of the blade passage, as well as an increase both of the number of blades, and the "impeller chord-spacing ratio", which essentially enhances the heat exchange efficiency. According to the second modification, the impeller is made in the form of a separating disk, the blades of the centrifugal fan are made on the one side of the disk, and those of the centripetal turbine - on the other side, which additionally permits provision of a two-stage heat-exchange system. Both stages are installed co-axially opposite each other with the front disks of the turbines, and the discharge connections of the centrifugal fans of one stage are made communicating with the inlet connections of the turbines of the other stage. In this case the centrifugal fan of one stage injects the flow of one of the heat-transfer agents to the turbine of the other stage. In the opposite direction the transfer of the other heat-transfer agent is accomplished. EFFECT: reduced overall dimensions and mass of the device due to the fact that the front disks of the turbines of both stages are made in the form of a single disk. 23 cl, 8 dwg

Description

 The invention relates to heat exchangers in which coolants are not mixed with each other, and can be used, for example, in ventilation and air conditioning systems for heat exchange between the intake and exhaust air flows.

 Known fan-heat exchanger [1], comprising a housing and two centrifugal fans mounted in the housing on the same shaft, oriented in opposite directions to each other. Two channels for coolants (air flows) with different temperatures are formed in the casing, separated by a heat exchange element made in the form of a corrugated radial partition mounted behind the edge of the fan impellers and having a disk separating the fans. When the fans rotate, the coolants through the corresponding suction nozzles enter the interscapular space of the fans and then, washing the corrugated radial partition of the heat exchange element from both sides, are removed from the housing through the corresponding discharge nozzles. Heat exchange is carried out through the corrugated partition during washing away of its faces by the heat carrier. The disadvantages of this design include large radial dimensions.

 Also known is a fan-heat exchanger [2], comprising a housing and two centrifugal fans mounted in the housing on one shaft, oriented in opposite directions to each other. Two channels for coolants with different temperatures are formed in the casing, separated by a wall that also separates both fans. The heat exchange element is made in the form of radial ribs installed on both surfaces of the partition beyond the edge of the impellers of the fans. When the fans rotate, the coolants through the corresponding suction nozzles enter the interscapular space of the fans and then, washing on both sides the radial ribs of the heat exchange element, are removed from the housing through the corresponding discharge nozzles. Heat exchange is carried out through the radial ribs and the partition itself. The disadvantages of this design should also include large radial dimensions.

 Closest to the claimed invention is a fan-heat exchanger [3], comprising a housing and an impeller of a double-sided centrifugal fan mounted in the housing, made in the form of a radially corrugated disk with an external rim, while the corrugation faces serve as radial blades. In the housing there is a partition adjacent to the outer rim of the impeller and dividing the housing into two isolated cavities (channels) for heat carriers with different temperatures. Thanks to this partition, two isolated centrifugal fans with a single double-sided impeller are formed in the casing. When the impeller rotates, the coolants through the corresponding suction nozzles in the housing enter the interscapular space of the fans and are then removed from the housing through the corresponding discharge nozzles. Heat transfer in such a device is carried out through the radial faces of the corrugated impeller.

 In the known fan-heat exchanger, the impeller, which is both a heat exchange surface, is formed by a radially corrugated surface. This design of the impeller leads to its low efficiency as an element of a centrifugal fan and as a heat exchanger.

 The first is explained by the fact that the function of the blades is performed by a radially corrugated surface. In this case, the air flow at the exit of the fan impeller has an excess pressure exceeding the pressure necessary to overcome the total hydraulic resistance of the fan. This requires an increase in power input. To eliminate this feature, typical of centrifugal fans with radial blades, blades of a different profile are needed, namely, the blades bent backward. Obviously, the manufacture of a corrugated disk with curved blades is a rather complicated technological task. The curvature of such corrugations will be determined by the allowable plastic deformation of the material from which the impeller is made. Moreover, such material properties conflict with the required stiffness of the impeller, which is subject to significant centrifugal forces during operation. This contradiction leads to the fact that it is not possible to produce a corrugated disk with a large curvature of the blades. Therefore, it is not possible for such a design to eliminate excess pressure and reduce the input power.

 The low heat transfer efficiency of the known device is explained by the following. To a certain extent, the heat exchange efficiency is affected by both the heat exchange surface area and the washing speed of this surface. In the case of radial blades, firstly, the heat transfer area will be minimal, since the radial blades have a minimum length, and secondly, the washing speed will decrease as it approaches the periphery of the impeller, which is due to the increase in air flow continuity cross-sectional area of the interscapular space to the periphery. Another factor of low heat transfer efficiency is the direct-flow circuit implemented in the device, when both heat carriers have unidirectional movement: in the known device, both heat carriers move from the center to the periphery of the impeller. At the same time, it is known that greater heat transfer efficiency can be achieved if a countercurrent circuit is used when the heat carriers have a counter direction of motion [4]. In relation to the known device, this means that one of the sides of the impeller should work as a centripetal. However, this cannot be achieved with radial blades, and the manufacture of a corrugated disk with curved blades, as already noted, is a rather complicated technological task, and taking into account the fact that the shape of the blades on both sides of the impeller will differ, making the impeller in the form of a corrugated disk does not succeeds.

 The technical problem to be solved by the claimed invention is directed is to increase the efficiency of heat transfer and reduce power consumption. Declares two options for solving the problem.

 The essence of the invention according to the first embodiment is that in the known fan-heat exchanger comprising a housing and a two-sided impeller installed in the housing, on one side of which are made centrifugal fan blades, while the housing is divided into two insulated cavities, which together with the impeller form two insulated sections, one of which is a centrifugal fan, according to the invention the impeller is made in the form of a dividing disk, and the said blades the centrifugal fan is made on one side of the separation disk, and the centripetal fan blades are made on its other side, which together forms the mentioned two-sided impeller, one side of which is the impeller of the centrifugal fan, and the other is the centripetal fan.

 Replacing the corrugated impeller disk with a solid disk, on both sides of which blades are made, allows the manufacture of the latter of any given shape, since such a design is no longer associated with the technology of manufacturing the corrugated surface. In particular, centripetal blades are made on one side of the impeller, which ensures its operation as a centripetal fan. In this case, the most effective countercurrent heat exchange scheme is organized. By changing the curvature of the blades, it is possible to change the area of the interscapular space normal to the blades, achieving a constant speed of washing the surface of the blades by the air flow. The specified embodiment of the blades, in contrast to the known one, can significantly increase both the number of blades and the "density of the impeller grating", that is, the ratio of the length of the blade to the distance between the blades at an average radius, which significantly increases the heat transfer efficiency. Despite the fact that in the inventive fan the heat exchange between the two heat carriers is additionally carried out through the introduced separation disk, the counter-current heat exchange scheme and the possibility of modifying the impeller blades due to the new design of the latter, not only compensate for the decrease in heat transfer efficiency associated with the additionally introduced separation disk, but increase overall this parameter of the device.

 To reduce the excess pressure at the outlet of the centrifugal fan and the inlet of the centripetal fan, the blades should be bent back.

 To increase the area of heat transfer in the inventive device, the fan blades should be made with a ratio of their length to the distance between the blades at an average radius of at least 10.

 Additionally, to increase the area of heat exchange between the fan blades, intermediate blades can be made on the periphery of the separation disk.

 Additionally, the fan blades can be made with a constant width of the interscapular channel, which ensures a uniform speed of the coolant in the interscapular channel and, accordingly, increases the heat transfer efficiency.

 Additionally, the impeller of the centripetal fan may have a solid front disk bonded to the blades, and the spacer disc may have an axial hole around which the outlet nozzle of the centripetal fan is made, communicating with the interscapular space of the impeller of the centripetal fan. Moreover, the said centrifugal fan outlet pipe is located inside the suction pipe of the centrifugal fan. Such an arrangement allows coolants to pass from one to the opposite side of the device, which simplifies its installation, for example, in ventilation and air conditioning systems, since it corresponds to the direction of the supply (or exhaust) air flow.

 Additionally, the impeller of the centrifugal fan may include a front disc fixed to the blades, having an axial hole for the passage of the suction coolant into the interscapular space of the centrifugal fan. The front disc covers the interscapular space, thereby reducing fan losses and increasing heat transfer efficiency.

 In addition, in order to reduce losses at the inlet around the axial hole of the front disk of the centrifugal fan impeller, an inlet pipe can be made that communicates with the interscapular space of the centrifugal fan impeller, while the inlet pipe is placed in the suction pipe of the centrifugal fan with a minimum clearance. In this case also, the impeller of the centripetal fan can have a solid front disk attached to the blades, and the separation disk has an axial hole around which the outlet pipe of the centripetal fan is made, communicating with the interscapular space of the impeller of the centripetal fan, while the said outlet nozzle of the centripetal fan is located inside centrifugal fan inlet. As shown above, this arrangement allows the passage of coolant from one to the opposite side of the device.

 The essence of the claimed invention in the second embodiment is that in a known fan-heat exchanger comprising a housing and a two-sided impeller installed in the housing, on one side of which are made centrifugal fan blades, while the housing is divided into two insulated cavities, which together with the impeller form two insulated sections, one of which is a centrifugal fan, according to the invention the impeller is made in the form of a dividing disk, and the said blades a centrifugal fan is made on one side of the separation disk, and turbine blades are made on its other side, which together forms an impeller, one side of which is the impeller of the centrifugal fan, and the other is a centripetal turbine.

 As in the first embodiment, replacing the corrugated disk of the impeller with a solid disk, on both sides of which blades are made, allows the latter to be made of any given shape, since such a design is no longer associated with the technology of manufacturing the corrugated surface. Centrifugal blades are made on one side of the impeller, which ensures its operation as a centrifugal fan, and on the other side of the centripetal turbine blades. In this case, the most effective countercurrent heat exchange scheme is organized. As in the first embodiment, by changing the curvature of the blades, it is possible to change the area of the interscapular space normal to the blades, achieving a constant speed of washing the surface of the blades by the air flow, and also significantly increase both the number of blades and the "density of the impeller grating".

 In addition, the execution on one side of the impeller of the turbine blades allows the use of the inventive device in systems with an external supercharger, while it is further possible to reduce the power consumption due to the fact that the coolant supplied under pressure through the turbine inlet starts to rotate the impeller. At a certain pressure, this may be enough to allow the impeller to rotate without an additional drive.

 In order to increase the productivity of the device, a supercharger can be additionally installed in the turbine inlet pipe. Moreover, in one of the particular cases of the turbine inlet pipe, it has the form of an annular hole coaxial to the impeller, and the supercharger is made in the form of an axial fan, the blades of which overlap the ring annulus of the turbine inlet. In another case, the turbine inlet is made in the form of an opening in its peripheral part, and the supercharger is made in the form of a centrifugal fan installed in this opening.

 As in the first embodiment, in order to reduce the excess pressure at the outlet of the centrifugal fan and the inlet of the turbine, the corresponding blades are made curved back.

 As in the first embodiment, in order to increase the heat exchange area, the blades of a centrifugal fan and / or centripetal turbine are manufactured with respect to their length to the interscapular distance at an average radius of at least 10.

 As in the first embodiment, in order to increase the heat exchange area between the centrifugal fan blades and / or the turbine blades, intermediate blades are made around the periphery of the separation disk.

 As in the first embodiment, the centrifugal fan blades and / or turbine blades can be made with a constant width of the interscapular channel, which ensures uniform velocity of the coolant in the interscapular channel and, accordingly, increases the heat transfer efficiency.

 As in the first embodiment, an arrangement is possible that allows the passage of coolants from one to the opposite side of the device. For this, the turbine impeller has a solid front disk fastened to the blades, and the separation disk has an axial hole around which the turbine outlet pipe is made, communicating with the interscapular space of the turbine impeller, and the turbine outlet pipe is located inside the suction pipe of the centrifugal fan.

 As in the first embodiment, to reduce fan losses and increase the efficiency of heat transfer, the impeller of a centrifugal fan may contain a front disc that is attached to the blades and has an axial hole for passage of the suction coolant into the interscapular space of the centrifugal fan.

 As in the first embodiment, in order to reduce losses at the inlet, an inlet pipe can be made around the axial hole of the front disk of the centrifugal fan impeller, which communicates with the interscapular space of the centrifugal fan impeller, while the inlet pipe is placed in the suction pipe of the centrifugal fan with the minimum allowable the gap. In this case, also, the turbine impeller can have a solid front disk attached to the blades, and the separation disk has an axial hole around which the turbine outlet pipe is made, communicating with the interscapular space of the turbine impeller, and the turbine outlet pipe is located inside the centrifugal fan inlet pipe .

 The presence of a centripetal turbine allows, in the latter case, the arrangement of the suction and discharge nozzles of a centrifugal fan, as well as the inlet and outlet nozzles of the turbine, to organize a two-stage heat transfer scheme. In this case, the described device is the first stage and is complemented by a second identical stage, with both stages installed coaxially and towards each other with the front turbine disks, and the discharge pipes of centrifugal fans of one stage are made in communication with the turbine inlets of the other stage. In this case, the suction pipe of the first stage and the outlet pipe of the second stage are respectively the inlet and outlet for one coolant, and the suction pipe of the second stage and the outlet pipe of the first stage are respectively the input and output for another coolant. With the indicated connection of two identical devices, the centrifugal fan of one of them (one stage) pumps the flow of one of the coolants into the turbine of the other device. In the opposite direction, the transfer of another coolant. Heat transfer between the heat carriers occurs in the manner indicated above - according to the counterflow scheme.

 The last particular case of the implementation of the claimed invention according to the second embodiment, on the one hand, can significantly increase heat transfer, since the heat carriers pass through two heat transfer stages, and on the other hand, it allows to optimize the dimensions of the two-stage device, since in this case the impellers can be mounted on one shaft, and for the rotation of the turbines do not require additional superchargers. In addition, it is possible to reduce the dimensions and weight of the device by making the front disks of the turbines of both stages as a whole, that is, as a single disk.

The essence of the claimed invention is illustrated by graphic materials, which depict:
FIG. 1 - fan-heat exchanger according to the first embodiment with a one-sided arrangement of suction and discharge nozzles of both centrifugal and centripetal fans;
FIG. 2 - fan-heat exchanger according to the first embodiment with an opposite arrangement of suction and discharge pipes of both centrifugal and centripetal fans;
FIG. 3 - an example of the execution of the blades of the impeller with a constant width of the interscapular channel;
FIG. 4 is an illustration of the relationships for calculating the profile of the blades with a constant width of the interscapular canal;
FIG. 5 - fan-heat exchanger according to the second embodiment with an axial fan as a supercharger in the turbine inlet pipe;
6 is a fan-heat exchanger according to the second embodiment with a centrifugal fan as a supercharger in the turbine inlet pipe;
FIG. 7 - a two-stage fan-heat exchanger according to the second embodiment with separate impellers;
FIG. 8 - a two-stage fan-heat exchanger according to the second embodiment with a common front disk for turbines of both stages.

 The inventive fan-heat exchanger according to the first embodiment (figures 1 and 2) consists of a housing 1, divided by a partition 2 into two cavities, forming a centrifugal fan section 3 and a centripetal fan section 4. The housing 1 has a suction 5 and a discharge 6 nozzles of a centrifugal fan, as well as an inlet 7 and an outlet 8 nozzles of a centripetal fan for the passage of coolants with different temperatures, the directions of which are shown by arrows. In the housing 1, on the shaft 9, an impeller is installed, consisting of a dividing disk 10 with centrifugal fan blades 11 and centripetal fan blades 12, which are normally bent on both sides and are rotated backward (relative to the direction of rotation). In the peripheral part of the blade 12 of the centripetal fan are deployed transverse to the direction of rotation and form the injection blades 13, providing suction of the coolant through the inlet pipe 7 of the centripetal fan. Both centrifugal and centripetal fans can additionally have intermediate blades installed in the peripheral part of the separation disk 10 between the blades 11 and 12, respectively, to increase the heat transfer area. 1, as an example, intermediate blades 14 for a centrifugal fan are shown. With its central part, the partition 2 is adjacent to the outer edge of the disk 10 through a sealing element 15 made, for example, of rubber or felt, due to which the centrifugal fan section 3 and the centripetal fan section 4 are isolated from each other.

 In FIG. 1 shows an example of a fan-heat exchanger with a single-sided arrangement of both nozzles 5 and 6 of a centrifugal fan, and nozzles 7 and 8 of a centripetal fan, and FIG. 2 is an example of a fan-heat exchanger with the location of these nozzles on opposite sides of the device. In the latter case, the discharge pipe 6 of the centrifugal fan is axially deployed in the opposite direction from the suction pipe 5. The device also contains (see figure 2) fastened to the blades 11 of the centrifugal fan front disk 16, having an opening 17 for passage of the suction coolant into the interscapular space of the centrifugal fan. Around the hole 17 of the front disk 16 is made of the inlet pipe 18, communicating with the interscapular space of the centrifugal fan and placed in the suction pipe 5 with a minimum clearance. A continuous front disk 19 is attached to the blades 12 of the centripetal fan, and the separation disk 10 has an axial hole 20 around which the outlet pipe 21 of the centripetal fan is made, communicating with the interscapular space of this fan, and the pipe 21 is located inside the inlet pipe 18 of the centrifugal fan. Due to the indicated design features of the device shown in FIG. 2, the heat carrier output streams are spaced on opposite sides of the fan-heat exchanger relative to the respective input streams.

An example of the execution of the blades 11 of a centrifugal fan with a constant width of the interscapular channel is shown in Fig.3. Figure 4 shows two adjacent blades (arc AB and arc CD) and the corresponding geometric construction for calculating the specified profile of the blades. For an arbitrary point E of the arc AB, lying at a distance r from the center O of the impeller, and the corresponding point F of the arc CD, the distance between which t (r) is the width of the interscapular channel, the point G of the arc CD, lying also at a distance r from the center, is determined About the impeller. The distance a (r) between points E and G for a large number of blades Z is approximately equal to the length of the arc EG, or a (r) ≈2πr / Z. Under these conditions, the value of t (r) can be defined as t (r) ≈a (r) • sinβ (r). Using numerical methods, it is possible for t (r) = T, where T = const, to calculate the values of the angle β (r), thereby determining the profile of the blade. In particular, Figures 3 and 4 show an example with the number of blades Z = 22 and the ratio of the minimum distance r _{0 of the} blade from the center O (point A) and the maximum r _k (point B): r ₀ = 0.4r _k . For this case, the values of β (r) are determined, which lie in the range: β (r ₀ ) = 34.22 ^o and β (r _to ) = 13.0 ^o . One of the ways to perform blades of the specified profile can be milling of the disk, the initial thickness of which is determined by the required depth of the interscapular channel. In this case, a mill with a diameter of T is used, and the program control of the milling machine uses the calculated values of β (r).

 The inventive device according to the first embodiment (see figure 1) works as follows. When the shaft 9 is rotated with a two-sided impeller fixed on it, air flows (coolants) having different temperatures enter from both sides through nozzles 5 and 7 and enter the space between the blades 11 and 12, respectively. In a centrifugal fan, air flow flows through the interscapular space to the periphery of the impeller, enters the cochlear cavity of the centrifugal section 3, and then through the discharge pipe 6 is discharged from the housing 1. In a centripetal fan, another air flow flows through the interscapular space to the center of the impeller and is discharged from the housing 1 through the outlet pipe 8. As air flows through the impeller, countercurrent heat exchange through the shovels occurs between them ki 11, 12 and the separation disk 10. In the design shown in figure 1, the intermediate blades 14 are also involved in the heat exchange process.

 In the device shown in figure 2, the heat transfer process occurs in the same way. This device differs from the device shown in figure 1, only the passage of air flow after the impeller. The air flow after the centrifugal fan exits through the discharge pipe 6, axially deployed in the opposite direction relative to the suction pipe 5, and the air flow after the centripetal fan exits through the opening 20 of the separation disk 10, enters the outlet pipe 21 of the centripetal fan, oriented in the axial direction in opposite side relative to the inlet 7 of this fan.

 The inventive single-stage fan-heat exchanger according to the second embodiment (Fig. 5) consists of a housing 1, divided by a partition 2 into two cavities, forming a centrifugal fan section 3 and a turbine section 22. The housing 1 has a suction 5 and a discharge 6 nozzles of a centrifugal fan, as well as an inlet 23 and an outlet 24 of the turbine nozzle for the passage of coolants with different temperatures, the directions of which are shown by arrows. The turbine inlet 23 is made in the form of an annular hole in the housing 1. Also, an impeller is installed in the housing 1, consisting of a spacer disk 10 with centrifugal fan blades 11 and turbine blades 25 made backward (relative to the direction of rotation) normally mounted on both sides thereof. . With its central part, the partition 2 is adjacent to the outer edge of the disk 10 through a sealing element 15 made, for example, of rubber or felt, due to which the centrifugal fan section 3 and the turbine section 22 are isolated from each other. The device also contains a front disc 16 fastened to the blades 11 of the centrifugal fan, having an opening 17 for the passage of the suction coolant into the interscapular space of the centrifugal fan. Around the hole 17 of the front disk 16 is made of the inlet pipe 18, communicating with the interscapular space of the centrifugal fan and placed in the suction pipe 5 with a minimum clearance. A continuous front disk 26 is attached to the blades 25 of the turbine, and the separation disk 10 has an axial hole 20 around which the turbine outlet pipe 24 is made, communicating with its interscapular space, and the pipe 24 is located inside the inlet pipe 18 of the centrifugal fan. In this case, the impeller is installed in the housing 1 on the shaft 9 through the front disk 26 of the turbine.

 The device also has a supercharger made in the form of an axial fan 27, the blades 28 of which are installed opposite the annular opening of the turbine inlet 23. The axial fan 27 can be mounted on the shaft 9, as shown in FIG. 5, or may have its own rotation shaft, not connected to the shaft 9 and driven by an independent drive. In the latter case, the drive of the fan 27 may be the drive of the entire device, since the turbine will provide rotation of the impeller and, accordingly, the operation of the centrifugal section 3.

 Another example implementation of the claimed invention in the second embodiment is presented in FIG. 6. In contrast to the previous example (figure 5) in this design, the turbine inlet 29 is made in the form of an opening in its peripheral part, and the supercharger is made in the form of a centrifugal fan 30 mounted opposite this opening.

 The inventive device according to the second embodiment (see figure 5 and 6) works as follows. The impeller is driven by a drive connected to the shaft 9, as well as due to one of the air flows (coolants) pumped into the turbine section 22 with an axial fan 27 (Fig. 5) or a centrifugal fan 30 (Fig. 6). With sufficient pressure, the impeller can only rotate due to the flow injected into the turbine section 22. Air flows having different temperatures from both sides enter through nozzles 5 and 22 and enter the space between the blades 11 and 25, respectively. In a centrifugal fan, the air flow flows through the interscapular space to the periphery of the impeller, enters the cochlear cavity of the centrifugal section 3, and then is discharged from the casing 1 through the discharge pipe 6. In the turbine, another air flow flows through the interscapular space to the center of the impeller through the separation hole 20 of the disk 10 enters the outlet pipe 21 and is removed from the housing 1. As air flows through the impeller, a countercurrent process occurs between them heat exchange through the blades 11, 25 and the separation disk 10.

 The two-stage fan-heat exchanger according to the second embodiment (see Figs. 7 and 8) consists of two identical stages - the first 31 and second 32, each of which, respectively, contains a centrifugal fan section 33 and 34, as well as a turbine section 35 and 36. Both stages 31 and 32 are made in the same way as the one-stage fan-heat exchanger described in FIGS. 5 and 6. The steps 31 and 32 are oriented towards each other by the front turbine disks and are mounted on the same shaft 9, driven in rotation from an external drive (on 7 and 8 are not shown). Partition 37 separates steps 31 and 32.

 The discharge pipe 38 of the section 33 of the centrifugal fan of the first stage 31 is connected to the inlet pipe 39 of the turbine section 36 of the second stage 32, and the discharge pipe 40 of the section 34 of the centrifugal fan of the second stage 32 is connected to the inlet pipe 41 of the turbine section 35 of the first stage 31. Suction pipe 42 of the first stage 31 and the outlet pipe 43 of the second stage 32 are respectively the input and output for one coolant, and the suction pipe 44 of the second stage 32 and the outlet pipe 45 of the first stage 31 are respectively But the input and output for another coolant.

 Preferred in the second embodiment is the implementation of the two-stage fan-heat exchanger shown in FIG. 8. In contrast to the example shown in Fig.7, in this device, the front disks of the turbine sections 35 and 36 of both stages 32 and 31 are made in the form of a single solid disk 46.

 The two-stage fan-heat exchanger according to the second embodiment (see Fig.7 and 8) works as follows. When the shaft 9 and, accordingly, the impellers of both stages 31 and 32 are rotated, the air flows (coolants) through the suction pipes 42 and 44 are sucked in by centrifugal fans of sections 33 and 34, respectively. From the output of the centrifugal fans of sections 33 and 36, air flows into the turbine sections 34 and 35, respectively, and then through the corresponding output pipes 43 and 45 are removed from the device. Thus, each air stream passes through both stages 31 and 32. As air flows through the impellers, the countercurrent heat exchange process described above passes through the blades of centrifugal fans, turbine blades, and separation discs. In the device shown in Fig. 8, heat transfer additionally occurs through a common front disk 46.

Sources of information
1. Japanese application 60-75634, F 28 D 9/00, declared. 04/10/85, publ. 07/06/94.

 2. Japanese application 60-75635, F 28 D 9/00, claimed. 04/10/85, publ. 07/06/94.

 3. Japanese application 61-86463, F 28 D 11/02, declared. 04/15/86, publ. 06/01/94 - a prototype.

 4. Kutateladze S. S. Fundamentals of the theory of heat transfer. - Novosibirsk: Nauka, 1970, p. 628.

Claims (23)

1. A fan-heat exchanger comprising a housing and a two-sided impeller installed in the housing, on one side of which are made centrifugal fan blades, the housing is divided into two insulated cavities, which together with the impeller form two insulated sections, one of which is a centrifugal fan characterized in that the impeller is made in the form of a separating disk, said centrifugal fan blades being made on one side of the separating disk, and on its other The blades of the centripetal fan are made on the other side, which together forms the mentioned two-sided impeller, one side of which is the impeller of the centrifugal fan, and the other is the centripetal fan. 2. The fan-heat exchanger according to claim 1, characterized in that the blades of the centrifugal fan and / or centripetal fan are bent backward. 3. The fan-heat exchanger according to claim 2, characterized in that the ratio of the length of the centrifugal fan blades and / or the centripetal fan blades to the distance between the said blades at an average radius of at least 10. 4. The fan-heat exchanger according to claim 2, characterized in that intermediate blades are made between the blades of the centrifugal fan and / or the blades of the centripetal fan on the periphery of the separation disk. 5. The fan-heat exchanger according to claim 2, characterized in that the centrifugal fan blades and / or the centripetal fan blades are made with a constant width of the interscapular channel. 6. The fan-heat exchanger according to claim 1, characterized in that the impeller of the centripetal fan has a continuous front disk fastened to the blades, and the separation disk has an axial hole around which the outlet pipe of the centripetal fan is connected, communicating with the interscapular space of the centripetal fan impeller, while said outlet nozzle of the centripetal fan is located inside the suction nozzle of the centrifugal fan. 7. The fan-heat exchanger according to claim 1, characterized in that the impeller of the centrifugal fan contains a front disc fastened to the blades, having an axial hole for the passage of the suction coolant into the interscapular space of the centrifugal fan. 8. The fan-heat exchanger according to claim 7, characterized in that around the axial hole of the front disk of the centrifugal fan impeller is made an inlet pipe in communication with the interscapular space of the centrifugal fan impeller, said inlet pipe being placed in the suction pipe of the centrifugal fan with the minimum allowable the gap. 9. The fan-heat exchanger according to claim 8, characterized in that the impeller of the centripetal fan has a solid front disk attached to the blades, and the separation disk has a solid front disk attached to the blades, and the separation disk has an axial hole around which the centripetal outlet pipe is made the fan in communication with the interscapular space of the impeller of the centripetal fan, while the said outlet nozzle of the centripetal fan is placed in Three of the inlet pipe of a centrifugal fan. 10. A fan-heat exchanger comprising a casing and a double-sided impeller installed in the casing, on one side of which are made centrifugal fan blades, the casing is divided into two insulated cavities, which together with the impeller form two insulated sections, one of which is a centrifugal fan characterized in that the impeller is made in the form of a separating disk, said centrifugal fan blades being made on one side of the separating disk, and on its other goy formed side turbine blades, which together form an impeller, one side of which is the impeller of said centrifugal fan, and another - centripetal turbine. 11. The fan-heat exchanger according to claim 10, characterized in that a supercharger is additionally installed in the turbine inlet pipe. 12. The fan-heat exchanger according to claim 11, characterized in that the turbine inlet pipe has the form of an annular hole coaxial to the impeller, and the supercharger is made in the form of an axial fan, the blades of which overlap the said annular opening of the turbine inlet. 13. The fan-heat exchanger according to claim 11, characterized in that the turbine inlet pipe is made in the form of a hole in its peripheral part, and the supercharger is made in the form of a centrifugal fan installed in this hole. 14. The fan-heat exchanger according to claim 10, characterized in that the blade of the centrifugal fan and / or turbine is made curved back. 15. The fan-heat exchanger according to 14, characterized in that the ratio of the length of the blades of the centrifugal fan and / or the blades of the turbine to the distance between the said blades on an average radius of at least 10. 16. The fan-heat exchanger according to 14, characterized in that between the blades of the centrifugal fan and / or the blades of the turbine on the periphery of the separation disk made intermediate blades. 17. The fan-heat exchanger according to 14, characterized in that the centrifugal fan blades and / or turbine blades are made with a constant width of the interscapular channel. 18. The fan-heat exchanger according to claim 10, characterized in that the impeller of the turbine has a solid front disk attached to the blades, and the separation disk has a solid front disk attached, and the separation disk has an axial hole around which the turbine outlet pipe communicates with the interscapular space of the turbine impeller, wherein said turbine outlet pipe is located inside the suction pipe of the centrifugal fan. 19. The fan-heat exchanger according to claim 10, characterized in that the impeller of the centrifugal fan contains a front disc fastened to the blades, having an axial hole for the passage of the suction coolant into the interscapular space of the centrifugal fan. 20. The fan-heat exchanger according to claim 19, characterized in that around the axial hole of the front disk of the centrifugal fan impeller is made an inlet pipe in communication with the interscapular space of the centrifugal fan impeller, said inlet pipe being placed in the suction pipe of the centrifugal fan with the minimum allowable the gap. 21. The fan-heat exchanger according to claim 20, characterized in that the turbine impeller has a continuous front disk fastened to the blades, and the separation disk has an axial hole around which the turbine outlet pipe is connected, communicating with the interscapular space of the turbine impeller, the turbine outlet pipe is located inside the centrifugal fan inlet pipe. 22. The fan-heat exchanger according to claim 18 or 21, characterized in that it is the first stage and further comprises a second stage identical to the first, both stages being aligned and facing the front turbine disks, and the discharge nozzles of the centrifugal fans of one stage are made communicating with the inlet nozzles of the turbines of another stage, the suction nozzle of the first stage and the outlet nozzle of the second stage are respectively the input and output for one coolant, and the suction nozzle the side of the second stage and the outlet pipe of the first stage are respectively the input and output for another coolant. 23. The fan-heat exchanger according to item 22, wherein the front discs of the turbines of both stages are integral.

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