PL180424B1 - Recuperative rotary heat exchanger and principle of its operation - Google Patents

Abstract

In a rotary regenerative heat exchanger of the kind having a rotor mounted in a casing, supports are provided for maintaining a certain clearance between the rotor and movable sector plates (6) connected to the casing and located closed to the rotor ends. Each support co-operates through a front surface on a sliding shoe (25) with an end surface (61) on a flange (12) on the rotor. Each support is provided with gas conduit means ending in the gas outlet means in the front surface and being connected to a gas source of a pressure sufficient to establish a gap between the front surface and the end surface (61) so that a cushion of gas is established between the surfaces as the gas escapes from the gas outlet means through the gap. According to the invention a sector plate (6) is provided with only one single gas cushion support located in the region of the symmetry line (69) of the plate (6), and at the outer corners of the plate (6) axially directed stabilizing projections (68) are provided, which face the end surface (61) of the flange (12). These supports (68) prevent tilting of the plate (6) as only one single gas cushion support is provided.

Description

The present invention relates to a rotary regenerative heat exchanger. It is known from the Swedish patent description No. 176 375 a regenerative rotary heat exchanger with a support in the form of rotating bodies mounted on the outer ends of circular sector plates, located at both ends of the rotating part and rotating on a flange located along the periphery on the upper and lower end of the rotor.

Thus, it is desirable to be able to maintain a constant play between the sector ends of the circular slices at the upper and lower ends, respectively. However, the surrounding medium turned out to be rough on the rolls. The roller bearings were abraded quickly, and dust and other particles stuck to the flanges and surface of the roller due to rotation, causing malfunctions.

It has been suggested to replace the rollers with shoes such as that disclosed in JP, A, 63-315 891. These shoes are made of a ceramic material in order to achieve high abrasion resistance. However, problems will arise if the sliders become slightly sloping, due to inaccuracy in assembly and / or heat distortion. In such cases, there will be a risk that the slider will only come into contact with the flange at a small portion of its sliding surface, resulting in an unacceptably high contact pressure. In addition, some type of external lubrication of the sliders is required, or significant frictional losses must be accepted.

WO 94/01730 discloses the use of carbon or graphite shoes instead of ceramic shoes. Such a glider eliminates the disadvantages associated with ceramic gliders. Graphite in particular has excellent lubricating properties and, like carbon, has the ability to keep the flanges of the rotating body clean when the lubricating layer of carbon or graphite is adhered to the flanges. The abrasion of the shoe also secures proper contact with the parallel contact surfaces so that contact takes place over the entire surface of the shoe. Carbon and graphite can also withstand high temperatures and an acidic environment. By abrasion of the sliders, they will gradually wear out and have to be replaced. However, the degree of abrasion will vary widely, so that one or more shoes may be so worn that the play will be zero, while the other shoes will be almost intact. Each shoe is thus adjustable in a direction perpendicular to the contact surface.

A similar solution is disclosed in WO 95/00809, in which a gauge rod is used adjacent to the shoe, the gauge rod pointing parallel to the direction of adjustment. The gauge rod can be moved momentarily from its rest position to a position where it contacts its associated flange and will indicate when the amount of play requires the shoe to be moved a distance such that the initial play is maintained.

Another solution is disclosed in Swedish patent specification No. 9302301-8, in which the abrasion problems are overcome in such a way that the shoe slides on a gas cushion created by gas supply between the shoe and the rotor flange. This avoids abrasion as there is no contact between the shoe and the collar.

However, the arrangement of the sliders hanging on the air cushions adds cost. Each shoe will be more complex and thus too complex to manufacture, and gas lines must be attached to each individual shoe.

Common to all of the support arrangements discussed above, both of the contact and non-contact type, is that at least two individual supports are provided for each sector plate. The reason for this is to ensure a stable support of the sector-shaped plate and to avoid tilting it. In theory, a single support in the center of the outer periphery of the plate should be sufficient, since the plate is supported at its inner end by two pivotal connections with the stationary center plate. Due to the flexibility of the movable sector plate and / or thermal deformation, however, in practice there will be a risk that the outer edges of the plate will tilt and hit the rotor when only one support is applied.

However, when using a non-contact type shoe that is more expensive than a conventional type shoe, it is desirable to reduce the number of such shoes.

The object of the invention is a rotary regenerative heat exchanger of the type under consideration, in which the number of shoes is reduced to a minimum.

A regenerative rotary heat exchanger having a substantially cylindrical rotor mounted in a housing which at least one end is provided with a circumferentially continuous outer end surface, and the housing is provided with plates on

At least one of the ends of the rotor, oriented substantially perpendicular to the axis of the rotor and close to a corresponding end of the rotor, the plates comprising movable sector plates, each sector plate being subjected to a resulting axial force towards the respective end of the rotor, and each the plate is provided with support units for maintaining a certain play between the sector plates and the respective end of the rotor, said support units comprising a gas cushion element, each of the gas cushion elements having a face facing the end face, the face having an outlet. gas that is connected by gas lines to a gas source at a pressure sufficient to produce between the face and end face of the fracture, against the axial force, thereby creating a gas cushion between the face and face face final, since the gas escapes from the gas outlet through the slot, according to the invention, it is characterized in that the support unit of at least one of the sector plates comprises individual gas cushion elements, and the sector plate is further provided with at least one axially projecting stabilizing projection facing towards guiding surface.

The individual elements of the gas cushion are located in the region of the radial axis of symmetry on the plane of the sector plate at its radially outer portion, and said sector plate has one stabilizing projection on each side of the axis of symmetry, each being adjacent a radial edge of the sector plate.

The individual elements of the gas cushion are located on one side of the radial symmetry axis on the plane of said sector plate in its radially outer part, and the sector plate has one stabilizing projection on the other side of the symmetry axis adjacent to the radial edge of the sector plate.

Each of the stabilizing projections has a radial projection which is slightly shorter than the distance between the sector plate and the corresponding flange guide surface, and is axially resilient.

The novel solution thus deviates from the traditional idea of using two or more supports for a circular sector plate when non-contact type supports are used. The problem of avoiding tilting is overcome by the stabilizing lugs. Since the protrusions are designed not to normally come into contact with the end face of the rotor flange, no abrasion problems will arise. If, however, there was a tendency for the plate to tilt, the protrusion would make contact with the flange and prevent tilting. The contact force in this case will be relatively low as the stabilizing lugs need not be involved in keeping the plate raised above the flange but only counter the deflection force. The lugs thus act as a type of stabilizer that sometimes contacts the flange, but for the most part leaves a little play to it.

By providing only one non-contact support for each sector plate, the number of airbag delivery devices is halved, which lowers manufacturing and maintenance costs and reduces the risk of failure.

The subject of the invention is shown in the drawing in an exemplary embodiment, in which: Fig. 1 shows a partial section through a first preferred embodiment of a heat exchanger according to the invention; Fig. 2 is an axial section through the support means, taken along line II-II in Fig. 1; Fig. 3 is a schematic plan view of a sector-shaped plate according to a first embodiment of the invention; Fig. 4 is a schematic section taken along the line IV-IV in Fig. 3; and Fig. 5 is a view similar to that of Fig. 3 showing a second embodiment of the invention.

The heat exchanger shown in Fig. 1 is of the conventional type, having a stationary casing 1 and a cylindrical rotor 2 containing a regenerative mass 3. The rotor 2 has a hub 4, an upper fixed sector-shaped central plate 5, and an upper rotatably movable plate connected thereto. 6 segment-shaped, and appropriate

180 424 a lower fixed central plate 7 and a lower movable plate 8 in the shape of a circular sector. The two plate assemblies 5, 6 and 7, 8 seal the upper and lower ends of the rotor 2 as tightly as possible, thus separating the heat exchange medium flowing to and from the rotor 2 through axial openings connected to the media conduits (not shown).

To this end, a device is disposed at the radially outer ends of each of the circular sector-shaped movable plates 6, 8, which device forms a support unit 10 for maintaining a certain play between the ends of the circular sector-shaped plates 6, 8 and the upper and lower. a flange 12 attached to the rotor 2 at its upper and lower circumferences, each flange 12 having an outer circumferentially continuous end guiding surface 61 cooperating with a face 62 connected to each of the support units 10.

Figure 2 shows a part of the housing 1, the upper flange 12 of the rotor 2, and the upper movable plate 6 in the shape of a sector of a circle. The support unit 10 is fixed in the sector hole of the upper plate 6 by means of bolts. The support assembly 10 comprises an outer sleeve 15 with a mounting flange 16 that is attached to the sector-shaped upper plate 6, together with an intermediate sealing ring 17, by means of bolts 18.

At the upper end, the outer sleeve 15 has an inner thread 19, and inside the outer sleeve 15 there is an inner sleeve 20 having an upper part with an outer thread partially threaded into the inner thread 19. At its lower end, the inner sleeve 20 has a seal 22 which seals tightly. adjacent to the inside of the outer sleeve 15. At the upper end of the inner sleeve 20 there is a nut 23 welded to it, and at its lower end a lower plate 24 is welded on. 24, circular slider made of graphite or carbon. The shoe 25 has a face 62 facing the circumferential continuous end face 61 of the flange 12 and parallel thereto. The upper end of the outer sleeve 15 has an outer ring flange 27 to which is screwed, by means of a mounting ring 29, ring gasket 30 and screws 31, a metal sealing bellows 28.

The lower end of the sealing bellows 28 is provided with a mounting ring 32 which is fastened by screws 33 and an intermediate seal 34 in the circular opening of the housing 1 such that a predetermined downward axial force will be exerted on the upper movable plate 6 due to the elasticity sealing bellows 28.

A measuring device 13 is attached parallel to the device 10 and close to its side, for measuring the play between the upper movable plate 6 and the flange 12. It comprises a pipe 40 fixed at its lower end in a circular sector opening 41 of the plate 6, and its upper end in the opening 42 of the flange 27 thus positioned inside the sealing bellows 28. Inside the tube 40 is a measuring rod 43, the upper end of which is attached in the position shown to the sleeve 44 by means of a spring not shown and an outer collar on the rod, which sleeve 44 is screwed onto tube 40. In this position, graduated portion 45 of upper end of bar 43 extends outward through sleeve 44 and lower end of bar 43 is flush with underside of sector-shaped upper plate 6.

Finally, as shown, a gauge 50 may be mounted having a probe 51 contacting the upper end of the graduated portion 45.

The support of the upper movable plate 6 in the shape of a circular segment in order to maintain the clearance between the plate 6 and the flange 12 is achieved by contactless interaction between the guide surface 61, which is the outer end surface of the rotatable annular flange 12, and the stationary face 62 of the slider 25.

In order to achieve this non-contact interaction, an airbag generating system is mounted between the surfaces 61, 62. The system comprises a pressurized gas supply 64 connected by a pipe 63 to the interior 65 of the inner sleeve 20 in which the shoe 25 is mounted. Through the shoe 25, the channels 66 connect the interior 65 of the interior sleeve 20 with the exit holes 67 in the end surface 62 of the shoe 25. The gas pressure is sufficient

To ensure that there is a continuous flow of gas from the outlets 67 and flowing between the face 62 and the guide surface 61 which are thus spaced apart from each other. In this way, a gas cushion is produced between these surfaces 61, 62 having an axial thickness of a fraction of a millimeter. Since there is no contact between the surfaces 61, 62, wear of the shoe 25 will not occur.

FIG. 3 shows a top plan view of the top movable plate 6 in the shape of a circular sector connected to the fixed central plate 5 by means of pivoting fasteners 71. At its outer periphery, the plate 6 in the shape of a circular sector is provided with one shoe 25 of the support unit 10. The skid 25 is located in the region of the symmetry axis 69 of the sector-shaped plate 6 and faces the guide surface 61 of the flange 12 of the rotor 2.

Since the sector-shaped upper plate 6 is supported at its radially outer end by only one shoe 25, this plate is less stable than when two or more skates are used and therefore there is a risk that the outer corners of the circular sector plate 6 can tilt. To avoid this effect, the sector-shaped plate is provided with an axially directed stabilizing projection 68 at its outer periphery near each end. As shown in Figure 3, the stabilizing lugs 68 are oriented so that they face the collar 12.

Figure 4 shows the operation of the stabilizing projections 68. As mentioned, the sector plate 6 is only lifted by means of the centrally located shoe 25 and the gas cushion created between the shoe 25 and the flange 12. Between the sector plate 6 and the collar 12 is held. a play of width S. If the sector plate 6 tilts, the tilting is interrupted by the contact between one of the stabilizing projections 68 and the flange 12. The stabilizing projections 68 are slightly shorter than the distance S between the sector plate 6 and the flange 12 so that the stabilization tabs 68 do not normally contact the flange 12. The contact force between the stabilization tab 68 and the flange 12 will be relatively low as the tab 68 does not help to keep the plate raised but only prevents tilting movement. For this reason, there is no need to consider wear on these protrusions or the use of self-lubricating material. The projections can therefore be made very simple.

The stabilizing lugs 68 are preferably resiliently mounted or made of a resilient material to provide softer resistance against tilting and to avoid kickback.

Alternatively, the shoe 25 may be located on one side of the symmetry axis 69 as shown in Fig. 5. In this case, the risk of tipping will be unidirectional and only one stabilizing projection 68 will be required on the other side of the symmetry axis 69 adjacent the radial edge 70. top plate 6 shaped like a circular sector 6.

Claims (5)

Patent claims 1. A rotary regenerative heat exchanger having a substantially cylindrical rotor mounted in a housing which at least one end is provided with a circumferentially continuous outer end surface and the housing is provided with plates on at least one end of the rotor oriented substantially perpendicular to the axis. of the rotor, and close to the respective end of the rotor, the plates comprising movable sector plates, each of the sector plates being subjected to a resulting axial force directed towards the respective end of the rotor, and each plate being provided with support devices for maintaining a certain clearance between the sector plates. and a respective rotor end, said support units comprising a gas cushion element, each of the gas cushion elements having a face facing the end face, the face having a gas outlet that is connected by gas conduits to the end face. a source of pressurized gas at a pressure sufficient to create a gap between the face and the end face against the axial force, thus creating a gas cushion between the face and end face as the gas escapes from the gas outlet through the gap, characterized in that the support unit (10 ) at least one of the sector plates (6,8) comprises single gas cushion elements, and the sector plate (6,8) is further provided with at least one axially extending stabilizing projection (68) facing the guide surface (61). 2. Heat exchanger according to claim A device according to claim 1, characterized in that said individual gas cushion elements are disposed in the region of a radial symmetry axis (69) on the plane of the sector plate (6,8) in its radially outer part, and said sector plate (6, 8) has one stabilizing projection each. (68) on each side of the symmetry axis (69), each being adjacent a radial edge (70) of the sector plate (6, 8). 3. Heat exchanger according to claim A gas cushion according to claim 1, characterized in that the individual elements of the gas cushion are located on one side of the radial symmetry axis (69), in the plane of said sector plate (6,8), in its radially outer part, and the sector plate (6,8) has one projection a stabilizer (68) on the other side of the symmetry axis (69) adjacent to the radial edge (70) of the sector plate (6,8). 4. Heat exchanger according to claim 2. A method according to claim 2 or 3, characterized in that each of the stabilizing projections (68) has a radial projection which is slightly shorter than the distance (S) between the circular sector plate (6, 8) and the corresponding guiding surface (61) of the flange (12) . 5. Heat exchanger according to claim The method of claim 4, wherein each of the stabilizing lugs (68) is axially resilient.