CS265957B1 - Rotating heat exchanger - Google Patents

Abstract

The rotor heat exchanger contains inside the housing concentrically main cylinder insert, additional cylindrical insert, provided with pins and forming with the inner surface of the main cylinder hollow space for viscous liquid flow and an auxiliary cylinder. Main cylindrical the insert and the additional cylindrical insert are fixed relative to each other turning by having a main cylindrical insert it is rigidly connected to the jacket and one from the pins of the additional cylindrical insert is in mechanical drive connection. Hollow space for viscous liquid flow is scraping device freely rotatably arranged which contains frames with scrapers.

Description

The invention relates to a heat exchanger, namely a rotor heat exchanger.

The invention can be used with particular advantage in the treatment of viscous liquids, for example polymer solutions.

Intensification of heat exchange is a serious problem when processing viscous liquids. The heat transfer coefficients are low here because it is difficult to achieve a high flow rate for these liquids and also because a boundary layer of large thickness is formed on the heat exchange surfaces.

Significant difficulties also occur in the treatment of liquids, which tend to deposit solid deposits on the heat exchange surfaces.

A rotor heat exchanger is known (SO AO 1 064 735) which comprises a main cylindrical insert concentrically arranged inside the housing around the longitudinal axis of the exchanger, which forms with the inner surface of the housing a hollow space for refrigerant flow, an additional cylindrical insert provided with pins and forming with the inner surface the main cylindrical insert a hollow space for the flow of viscous liquid, and an auxiliary cylindrical insert which forms with the inner surface ^{J of the} additional cylindrical insert a hollow space for coolant penetration, the main cylindrical insert and the additional cylindrical insert being fixed relative to each other by an external drive rotation. This heat exchanger further comprises a scraper device, which consists of frames freely rotatably mounted in a hollow space for the flow of viscous liquid, of scraper attached to the frames and of two pins attached to the frames. The relative rotation of the main cylinder liner and the auxiliary cylinder liner is enabled in this heat exchanger by mechanically connecting the main cylinder liner to the rotation drive and by rigidly connecting the auxiliary cylinder liner to the housing.

However, the rotation of the main cylinder liner in this heat exchanger causes the viscous liquid to rotate together with the main cylinder liner adjacent to its inner surface, thereby hindering the radial movement of the viscous liquid. This then results in a reduction in heat exchange.

The object of the invention is to obviate the said disadvantages and to provide such a rotor heat exchanger in which the main cylinder liner and the additional cylinder liner would be connected to the other components of the heat exchanger so as to achieve intensification of the heat exchange by their relative rotation.

The invention is a rotary heat exchanger, which comprises, inside the casing about the longitudinal axis of the heat exchanger concentrically disposed cylindrical main liner which forms the inner surface of the shell cavity to a refrigerant flow, an additional cylindrical insert having pins and vytyáře- _e a r a cylindrical inner surface of the main a hollow space for the flow of viscous liquid, and an auxiliary cylindrical insert which forms with the inner surface of the additional cylindrical insert a hollow space for the flow of coolant, the main cylindrical insert and the additional cylindrical insert being fixed with relative rotation and one of them by an actuator located outside the housing. rotation, and further comprising a scraping device which consists of frames rotatably mounted in a hollow space for the flow of viscous liquid, of hooks attached to the frames and of two pins attached to the frames. The essence of the invention lies in the fact that the relative rotation of the main cylindrical insert and the additional cylindrical insert is enabled by a rigid connection of the main cylindrical insert with the housing and a mechanical connection of one of the pins of the additional cylindrical insert with a rotation drive.

The rotor heat exchanger according to the invention is preferably further provided with two reducers, each of which comprises two main gears, one main gear being mounted on a respective pin of an additional cylindrical insert acting as its drive shaft, and the other main gear being mounted on the respective pin of the scraper device, acting as its driven shaft.

It is preferred that for each two-stage gearbox, the diameter of the main gear mounted on the drive shaft is smaller or larger than the diameter of the main gear mounted on the driven shaft.

The invention provides for the displacement of the outer layers of the viscous liquid to be treated while creating Tylor vortices, which facilitate the intensive mixing of said viscous liquids, thereby intensifying the heat exchange.

Hereinafter, the invention will be explained in more detail by describing its exemplary specific embodiments with reference to the accompanying drawings, in which Fig. 1 shows a general view of a rotor heat exchanger according to the invention in longitudinal section, Fig. 2 an overall view of the rotor heat exchanger according to FIG. 1 with two-stage reducers, FIG. 4 a section along the line IV - IV in FIG. 3.

The rotor heat exchanger comprises a main cylindrical insert 2, an additional cylindrical insert and an auxiliary cylindrical insert 2, which are housed concentrically in the housing 2 (Fig. 1). The inner surface 2 of the housing 2 forms with the outer surface 6 of the main cylindrical insert 2 a hollow space 2 for the flow of coolant. Inside the main surface 2 of the cylinder liner 2 and the outer surface of the auxiliary cylinder 2 2 j ^e a hollow space 10 for the flow of viscous liquid. The inner surface 11 of the additional cylindrical insert 2 forms with the outer surface 12 of the auxiliary cylindrical insert 2 a hollow space 13 for the flow of coolant. Frames 14 (Figs. 1 and 2) of the scraper device 22 are provided in the hollow space 10. Scrapers 22 are attached to each of the frames 14. · Hollow pins 22, 22 are suitably attached to the front walls 17, 12 of the auxiliary cylindrical insert 2. On the walls 21, 22 of the additional cylindrical insert 2, pins 22 '21 are suitably fixed ^{with the} possibility of rotation with respect to the longitudinal axis 25 of the heat exchanger. Bearings 22 '22 are suitably attached to the transverse (relative to the axis 25) ribs 22' 22 of the frame 14 of the device 15. Bearings 32, 31 with respective pairs of partitions 22 '33 ^and 21 are placed on the pin 23 of the additional cylindrical insert 2. pin 24 is provided a bearing 36 with the partitions 37, 38 and 19 of the bearing pin 39 with the partitions £ 0, 41. a pivot 23 of the auxiliary cylinder 2 ^e j is connected mechanically through the clutch half 42, disposed on its front surface 43, a drive 44 rotation . In the part 45 of the surface of the casing 11 there is a neck 46 for the supply of refrigerant to the hollow space £ 3- In the part 47 of the surface of the casing 6 there is a neck 48 for draining water from the hollow space 13. On the front wall 49 of the casing 6 there is a neck 50 for liquid into the hollow space 10 and on its front wall 51 a neck 52 for discharging viscous liquid from the hollow space 10. In the portion 53 of the shell surface JL there is a neck 54 for supplying coolant to the hollow space 2 next to its front wall 51 and next to its front wall 49. a neck 55 for discharging refrigerant from the hollow space 6. .

According to another embodiment of the invention, the rotor heat exchanger comprises two two-stage reducers ££, 57 (Fig. 3), the respective pins of the additional cylindrical insert 2 serving as their drive shafts £ 2 '22 (Figs. 3 and 4) ^and the drive shafts 22 serving as their drive shafts 22. The main pins of the device 15 are suitably attached to the drive shafts 58, 59 '. The main gears £ 2' 63 and the driven shafts £ 0, 61 of the main gears 64, £ 5 are suitably attached. Each of the reducers 56, 57 comprises two additional shafts £ 6, 67 and £ 2, £ 2. ^{Two additional gears 70, 71 and 72, 73 are attached to} each of the shafts 66, 67 of the reducer 56 and to each of the shafts 68, 69 of the reducer 57, two additional gears 74, 75 and 76, 77 are mounted.

The rotor heat exchanger according to Figs. 1 and 2 operates as follows.

The refrigerant stream is fed through the neck 54 to the hollow space 6 and the consumed refrigerant is discharged from this hollow space through the neck 55. Another refrigerant stream is fed through the neck 46 to the hollow space 13 at the same time and the consumed refrigerant is discharged from this hollow space through the neck 48. The viscous liquid to be treated is fed into the hollow space 10 through a neck 50. When rotating the additional cylindrical insert 2 'which acts as a rotor of the heat exchanger, a part of the scrapers 6 located in the immediate vicinity of the outer surface 2 of the additional cylindrical insert 2 acts ^on each other relative to this outer surface 9. The resulting torque causes the entire scraper 15 to move. The frames of the scraper 15 begin to rotate and, as a result, another part of the scrapers located in the immediate vicinity of the inner surface 2 of the main cylinder insert begins. which acts as a stator of the heat exchanger to interact with this inner surface £. In this case, a braking torque is generated for the frames £ 4, which acts against the torque of these frames 14.

At the same time, an additional braking torque is generated due to the resistance exerted by the viscous liquid against the rotation of the frames of the device 15.

In this respect, the rotational speed of the device 15 is less than the angular velocity of the additional cylindrical insert 6, thus simultaneously cleaning the surfaces 6, 6 of the cylindrical inserts 6, the scrapers 16 due to the favorable load distribution acting on the frames 14 operating according to the known principle of the simple beam, there is minimal deformation of the frames 14. In addition, in the hollow space 10 between the main cylindrical insert 2 (stator) and the additional cylindrical insert 6 (rotor) in the volume of processed viscous liquid Tylor vortices, which contribute significantly to intensification of radial circulation. liquid in this hollow space 10 and thus to substantially increase the heat transfer coefficient to both surfaces e and 9.

According to the invention, the high heat transfer coefficients are maintained even when processing any viscous liquid which tends to precipitate a solid precipitate on all surfaces in contact with it. The processing volume of the subjected viscous liquid is discharged through the neck 52.

The rotor heat exchanger according to Figs. 3 and 4 operates similarly to the heat exchanger described above. In this case, the motor 44 drives the drive shafts 58, 59 of the two-stage gearboxes 56, 57 to rotate via the coupling half. to its main gear 64. From the gear 64, the motion is transmitted to the driven shaft 60 and from there to the frame 14 of the device 5. Similarly, in the gearbox 57, the movement of the shaft 59 is transmitted to the main gear 63 and from there via a respective pair of additional gears 74, 75 and 76, 77 to its main gear 65. From the gear 65 the movement is transmitted to and from the driven shaft 61. according to the selected diameters of the main gears 62, 63 transmitting the movement of the drive shafts £ 8, 59, relative to the diameters of the main gears 64, 65 transmitting the movement of the driven shafts 60, £ 5, the device 15 rotates at a lower rotational speed ( in case the diameter of the gears 64, 65 is larger than the diameter of the gears 62, ££) and at a higher rotational speed (in case the diameter of the gears 64, 65 is smaller than the diameter of the gears 62, £ 3).

If the diameter of the gears 64, 65 is larger than the diameter of the gears 62, ££ and the device 15 rotates at a lower angular speed than the angular speed of the additional cylindrical insert (rotor), they form inside the hollow space 10 in the volume of viscous liquid being processed. Tylor's beliefs mentioned above.

A certain delay in the rotation of the frames 14 of the device 15 compared to the rotation of the additional cylindrical insert £ (rotor) makes it possible to ensure simultaneous cleaning of the surfaces £ and £ of the scraper ££ without affecting the intensity of the Tylor viruses. This not only substantially intensifies the heat exchange, but also makes it possible to keep these surfaces £ and £ in working order even during the processing of viscous liquids, which tend to form deposits on the surfaces in contact with them.

In case the diameter of the gears 64, 65 is smaller than the diameter of the gears 62, £ 3 and the device 15 rotates at a higher angular speed than the angular speed of the additional cylindrical insert (rotor), Tylor vortices do not arise. This embodiment of the device according to the invention is suitable for processing liquids with a viscosity at which the formation of Tylor vortices is ruled out. In this case, increasing the speed of the additional cylinder liner 6 with an increased energy input is ineffective. Instead, the speed of interaction of the scrapers 16 with the surfaces £ and £, i.e. the number of revolutions of the device 15, is increased to intensify the heat exchange.

The invention makes it possible to ensure heat exchange in the treatment of liquids with a wide range of viscosity values and other physicochemical properties.

Claims (3)

A rotor heat exchanger comprising a main cylindrical insert concentrically arranged around the longitudinal axis of the exchanger inside the housing, which forms with the inner surface of the housing a hollow space for refrigerant flow, an additional cylindrical insert provided with pins and forming with the inner surface of the main cylindrical insert a hollow space for flow viscous liquids, and an auxiliary cylinder liner which forms a hollow space for the flow of coolant with the inner surface of the auxiliary cylinder liner, the main cylinder liner and the auxiliary cylinder liner being fixed to one of them by relative rotation by an outer drive a scraper device which consists of frames rotatably mounted in a hollow space for the flow of viscous liquid, of scrapers attached to the frames and of two pins attached to the frames, characterized in that for relative rotation of the main cylindrical insert (2) and the additional cylindrical insert (3) a rigid connection of the main cylindrical insert (2) to the housing (1) and a mechanical connection are made one of the pins (23, 24) of the additional cylindrical insert (3) with the rotation drive (44). 2. A rotor heat exchanger according to claim 1, characterized in that it further comprises two two-stage reducers (56, 57), each of which is provided with two main gears (62, 63), one main gear being mounted on a respective pin. an additional cylindrical insert (3) which acts as a drive shaft (58, 59), and a second main gear (64, 65) is mounted on a respective pin of the scraper device (15) which acts as a driven shaft (60, 61). 3. A rotor heat exchanger according to claim 2, characterized in that for each two-stage gearbox (56, 57) the diameter of the main gear (62, 63) mounted on the drive shaft (58, 59) is smaller or larger than the diameter of the main gear. a gear wheel (64, 65) mounted on the driven shaft (60, 61).