DE69611519T2 - REGENERATIVE HEAT EXCHANGER AND METHOD FOR OPERATING A REGENERATIVE HEAT EXCHANGER - Google Patents

Description

The present invention relates in a first point to a regenerative heat exchanger of the type described in the preamble of claim 1 and in a second point to a method for operating a regenerative heat exchanger as set out in the preamble of claim 8.

Such a heat exchanger is known, for example, from SE 176 375, which describes a support in the form of rolling elements that are attached to the outer ends of the sector-shaped plates near the two ends of the rotating part and roll on a flange along the circumference on the top and bottom of the rotor.

The intention was to allow a constant clearance to be maintained between the ends of the sector-shaped plates and the top and bottom surfaces. However, the environment proved to be demanding for the rolling elements. The rolling element bearings wore out quickly and dirt and particles adhered to the flanges and the surfaces of the rolling elements as they rolled, resulting in failures.

It has been proposed to replace the rolling elements with sliding shoes, as proposed in JP,A,63-315 891. These sliding shoes are made of ceramic to give them high wear resistance. However, problems arise when the sliding shoe is slightly tilted due to assembly inaccuracies and/or thermal deformations. In such cases, there is a risk that the sliding shoe the flange is only touched by a small part of its sliding surface with unacceptably high contact pressure as a result. In addition, some form of external lubrication of the sliding shoes is required or significant friction losses must be accepted.

In WO 94/01730 an improvement has been proposed by using carbon or graphite sliding shoes instead of ceramic sliding shoes. Such a sliding shoe avoids the disadvantages of a sliding shoe made of ceramic materials. In particular, graphite has excellent lubricating properties and, similar to carbon, it has an ability to keep the flanges of the rotating body clean when a lubricating layer of carbon or graphite adheres to the flanges. The abrasion of the sliding shoe also ensures correct contact with parallel contact surfaces so that contact takes place over the entire sliding shoe surface. Carbon and graphite also show good behavior in the high temperature and acidic environment present. Due to the abrasion, the sliding shoes are gradually worn down and must be replaced. The degree of abrasion, however, varies widely, so that one or more sliding shoes can be so worn that the play reaches zero, whereas other sliding shoes can be almost unaffected. Each sliding shoe is therefore adjustable in a direction perpendicular to the contact surface. A similar solution is described in WO 95/00809, where a measuring rod is provided near the sliding shoe, which is aligned parallel to the adjustment direction. The measuring rod can be brought into contact with the corresponding flange for a short time from a rest position and indicates when the size of the play requires the sliding shoe to be readjusted by a certain distance. required so that the original game is restored.

Another solution is described in WO-A-9501541, where the abrasion problems are solved by having the sliding shoe slide on a gas cushion created by supplying pressurized gas between the sliding shoe and a flange on the rotor. Consequently, the abrasion is avoided by the fact that there is no contact between the sliding shoe and the flange.

However, this requires the presence of a source of compressed gas or makes it necessary to equip the plant with a compressor to produce the compressed gas. This means a considerable increase in costs both for the manufacture of the heat exchanger and for the production of the compressed gas.

The object of the present invention is to provide a regenerative heat exchanger of the type in question, which provides contact-free support means without the disadvantages inherent in already known designs.

According to the invention, the object is achieved in that a rotating heat exchanger of the type described in the preamble of claim 1 has the features set out in the characterizing part of this claim and in a further point in that a method as described in the preamble of claim 8 comprises the measures set out in the characterizing part of this claim.

By achieving contact-free interaction between the guided surface and the circumferentially continuous guiding surface, e.g. a flange pressurised by the supply of water, there is no need to provide for pressurised gas production, which is much more cumbersome and costly than supplying water.

The invention is particularly, but not exclusively, suitable for heat exchangers in which the plates are sector-shaped plates arranged close to the end faces of the rotor so that the support means are axially aligned.

The water supply preferably comprises a plurality of channels through a spacer element. These and other preferred embodiments of the invention are described in the dependent claims.

The invention is explained in more detail by the following detailed description of preferred embodiments and with reference to the attached drawings. They show:

Fig. 1 is a partial axial section of a first preferred embodiment of a heat exchanger according to the invention;

Fig. 2 shows an axial section through the support means along the line II-II of Fig. 1;

Fig. 3 is a section corresponding to Fig. 1, but showing a second embodiment of the invention;

Fig. 4 is a partial axial section through the support means according to a third embodiment of the invention and

Fig. 5 is a section corresponding to Fig. 4, but showing a fourth embodiment of the invention.

The heat exchanger shown in Fig. 1 is of conventional type and comprises a stationary housing 1 and a cylindrical rotor 2 containing the regenerative mass 3. The rotor comprises a hub 4, an upper, fixed, sector-shaped central plate 5 with a movable sector plate 6 pivotally mounted thereon, and a corresponding lower, fixed central plate 7 and a movable sector plate 8. The two sets of plates 5, 6 and 7, 8 function to seal as tightly as possible against the upper and lower ends of the rotor 2 and thereby separate the heat-exchanging medium flowing in and out of the rotor through axial openings connected to medium lines (not shown).

For this purpose, the radially outer ends of the movable sector plates 6, 8 are each provided with two devices 10 which form support means for maintaining a certain clearance between the ends of the sector plates 6, 8 and upper and lower annular edge flanges 12 attached to the rotor along its upper and lower circumferences, each flange having an outer circumferentially continuous guide surface 61 for cooperating with guided surfaces which are respectively connected to the devices 10.

Fig. 2 shows a part of the housing and the upper edge flange 12 of the rotor as well as the upper movable sector plate 6. One of the devices 10 is fastened in a hole in the sector plate 6 by means of screws. The device comprises an outer sleeve 15 with a mounting flange 16 which is attached to the sector plate 6 with an intermediate sealing ring 17 by means of screws 18.

At its upper end, the outer sleeve 15 has an internal thread 19, and in the outer sleeve 15 there is an inner sleeve 20 with an upper part with an external thread that is partially screwed into the internal thread 19. At its lower end, the sleeve is provided with a seal that sealingly contacts the inside of the outer sleeve 15. The upper end of the inner sleeve 20 is provided with a nut 23 welded to it, while at its lower end there is a base plate 24 welded to it. A circular sliding shoe 25 made of graphite or carbon is replaceably attached to the underside of the base plate 24 by means of a countersunk screw 26 screwed into the base plate 24. The sliding shoe 25 has a front surface 62 that faces the circumferentially continuous guiding surface 61 of the flange 12 and lies parallel to it.

The upper end of the outer sleeve 15 is provided with an outer ring flange 27, to which the upper end of a sealing bellows 28 made of metal is screwed by means of a mounting ring 29, an annular seal 30 and screws 31.

The lower end of the bellows 28 is provided with a mounting ring 32, which is fixed to the bellows 28 by means of screws 33 and an intermediate Seal 34 is mounted in a circular hole in the housing 1 such that a predetermined axial force is applied downwards to the plate 6 due to the spring action of the bellows 28.

Parallel to the device 10 and close to its side, a measuring device 13 is provided for measuring the clearance between the plate 6 and the flange 12. It comprises a tube 40 which is fitted with its lower end in a hole 41 in the sector plate 6 and with its upper end in a hole 42 in the flange 27 and therefore extends inside the bellows 28. In the tube lies a measuring rod 43, the upper end of which, in the position shown, is fastened by means of a spring (not shown) and an external flange on the rod to a sleeve 44 which is screwed onto the tube 40. In this position, a corrugated section 45 of the upper end of the rod 43 projects outwards through the sleeve 44 and the foot end of the rod 43 is flush with the underside of the sector plate 6.

In certain circumstances, a dial gauge 50 may be provided as shown with a sensor 51 which contacts the upper end of the grooved area 45.

The support of the movable sector plate 6 for maintaining a clearance between the plate 6 and the flange 12 is achieved by a contact-free interaction between a guiding surface 41, which is the outer end surface of the rotating flange 12, and a stationary guided surface 62, which is the front surface of the sliding shoe 25. In order to obtain this contact-free interaction, means for building up a cushion of water vapor between these surfaces are 61, 62. These means comprise a pressurized water supply 64 connected by a conduit 63 to the interior 65 of the sleeve 20 to which the sliding shoe 25 is attached. Through the sliding shoe 25, channels 66 connect the interior 65 of the sleeve 20 to the end face 62 of the sliding shoe 25. This conducts water from the water supply 64 to the guiding surface 61 of the flange 12. The temperature of the flange is approximately 350ºC, resulting in total or partial evaporation of the water which comes into contact with it. The pressure of the water is sufficient to cause the water to flow continuously from the channels 66 and exit between the guided surface 62 and the guiding surface 61, which are thereby forced away from each other. In this way, a cushion of evaporated water is formed between the surfaces 61, 62, which has an axial thickness of a fraction of a millimeter. Since there is no contact between the surfaces 61, 62, no wear of the sliding shoe occurs. Adequate water pressure can be achieved in some applications by ordinary line pressure, but in other applications a pump may be necessary to increase the pressure.

Fig. 3 shows an alternative embodiment of the invention, according to which sealing plates 70 are additionally or alternatively provided close to the cylindrical surface of the rotor 2. These plates 70 are curved to correspond to the cylindrical surface and are substantially rectangular. The plates are radially movable by means not shown and cooperate with axially aligned edge flanges 71 at the upper and lower ends of the rotor 2.

Between each movable plate 70 and the flanges 71, a certain clearance must be maintained, which is achieved by means of devices 10' which are of the same type as the supports 10 used to maintain the clearance between the sector plates 6, 8 and the ends of the rotor 2. When both sector-shaped sealing plates 6, 8 and the curved plates 70 are used, it is possible to provide both with support means according to the invention or to provide either the sector plates or the curved plates with such means and to have an easier assembly of the other plates.

The generation of the steam cushion is influenced by how the channels are arranged through the sliding shoe. Fig. 4 and 5 show two preferred alternatives in which these channels 66 are arranged to promote the formation of the steam cushion. In Fig. 4, the channels 66 open into a recess 67 on the foot side, which faces the guiding surface 61 of the flange 12, the walls 68 of the recess 67 preferably being inclined. In Fig. 5, the channels 66 are inclined relative to the axial direction and meet the guided surface 62 of the sliding shoe 25 in the middle.

Claims (8)

1. Regenerative heat exchanger with a substantially cylindrical rotor (2) mounted in a housing (1) provided with at least one movable plate (6, 8) arranged close to the rotor (2) and subjected to a resulting force in the direction of the rotor (2), the heat exchanger being provided with support means (10, 61, 62) for maintaining a certain clearance between the rotor (2) and the movable plate (6, 8), which support means comprise a circumferentially continuous guide surface (61) on the rotor (2) and at least one guided surface (62) connected to the movable plate (6, 8) and lying parallel to the guide surface (61), characterized in that the movable plate (6, 8) is provided with water conduction means (63, 65, 66; 67), which end in the guided surface (62) and are connected to a water source (64) at a certain pressure in order to form a gap between the guided surface (62) and the guide surface (61) against the action of the resulting force and thereby build up a cushion of at least partially evaporated water between the surfaces (61, 62), since the water is at least partially evaporated by contact with the guide surface (61) and exits from the conduit means (63, 65, 66; 67) through the gap. 2. Heat exchanger according to claim 1, characterized in that the at least one movable plate (6, 8) is arranged near one of the ends of the rotor (2) in an orientation in is arranged substantially perpendicular to the axis of the rotor (2) and separates axially aligned openings which are in communication with lines for heat-transferring media, wherein the guide surface (61) is arranged on a corner flange (12) on the circumference of the associated end of the rotor (2) and is perpendicular to the axis of the rotor (2). 3. Heat exchanger according to claim 2, characterized in that the at least one movable plate (6, 8) is sector-shaped and has a radially outer end near the corner flange (12) and a radially inner end which is pivotally connected to a central plate (5, 7) which is rigidly connected to the housing (1), the movable plate (6, 8) being provided with two guided surfaces (62) which are distributed around the circumference and are individually axially adjustable with respect to the movable plate (6, 8). 4. Heat exchanger according to one of claims 1 to 3, characterized in that each guided surface (62) is a surface on a sliding shoe (25) and the water conducting means comprise a plurality of channels (66) and end through a plurality of openings in the guided surface (62). 5. Heat exchanger according to one of claims 1 to 3, characterized in that the guided surface (62) is a surface on a sliding shoe (25) and the water conducting means comprise at least one channel (66) through the sliding shoe and a recess (67) in the guided surface (62), the channel (66) ending in the recess (67) and this has a larger flow area than the channel (66). 6. Heat exchanger according to claim 5, characterized in that the recess (67) has a conical wall (68) which widens in the direction of the guided surface (62). 7. Heat exchanger according to claim 4, characterized in that at least some of the channels (66) are inclined with respect to the axis of the rotor (2). 8. Method for operating a regenerative heat exchanger for maintaining a certain clearance between a substantially cylindrical rotor (2) of the heat exchanger and a movable plate (6, 8) arranged near the rotor and connected to a housing (1) of the heat exchanger, the rotor (2) having a circumferentially continuous guide surface (61) which cooperates with a guided surface (62) which is connected to the movable plate (6, 8) and faces parallel to the guide surface (61), characterized in that water is supplied through water conducting means (63, 65, 66; 67) which end in the guided surface (62), the water having sufficient pressure to form a gap between the guided surface (62) and the guide surface (61) against the action of the resulting force and thereby build up a cushion of at least partially evaporated water between the surfaces (61, 62), since the water is at least partially evaporated by contact with the guide surface (61) and exits the conducting means (63, 65, 66; 67) through the gap.