DE818960C - Circulating regenerative heat exchanger - Google Patents

Description

Recirculating Regenerative Heat Exchanger The invention relates to on heat exchangers for gas turbines of all types of the regenerative drum design which is the rotor, which consists of a hollow drum made of metal or ceramic material consists, circulates inside a housing, through which both the exhaust gases and the compressed cold air flow. The paths of exhaust gases and compressed air are separated by seals that run along and around the ends of the drum and so divide the drum into a hot gas and cold air side, in which the gases flow alternately in countercurrent through the hollow bodies. Give the hot exhaust gases their heat to the hollow bodies as it flows through the hot gas side of the drum in this part of the drum, so that the hot hollow body as the drum rotates pass into the cold air side, where the heat from the hollow bodies to the cold, compressed air is released. With this type of regenerator, the length of the Gas or air path through the hollow body can be very small, but the temperature difference between the inside diameter and the outside diameter of the drum is the full one Temperature difference between the temperatures of the hot gas and the cold one Air, so that the different parts of the drum very large temperature differences are subject. To maintain an effective seal along the drum, it is important to keep the drum as cylindrical as possible in its shape, The object of the present invention is to provide a drum that can as a result of the temperature differences in the metal of the drum Tensions are not forgiven.

The arrangement of the regenerative heat exchanger according to the invention for gas turbines is the following: Are in a rotating hollow drum the concentric inner and outer walls by a number of radial, in uniform Spaced ribs connected which form the drum in a number divide by longitudinal chambers.

The inner and outer walls of the chamber have holes or slots, through which the hot gases and cold air flow.

The through the gas-tight ribs and through the inner and outer walls The longitudinal chambers formed in the drum contain hollow bodies through which the hot gases and the cold air flows through it and which flows from the hot gases to the cold Absorb heat to be given off by air.

The drum is divided into several annular compartments in the longitudinal direction divided, which z. B. are connected by bolts on their cold side, while they have an axial play on the hot side to accommodate any expansion of the hot Side in relation to the cold side, without changes in relation to it Concentricity can arise. There are also radial ones on the hot side of the drum Slits are provided in the ribs between the chambers, so that a relative expansion in the circumferential direction between the hot and cold sides of the drum with a Minimum of changes in the concentricity of the wall of the drum added can be.

In the schematic drawing showing an embodiment of the present Invention illustrates, Fig. I shows a cross section of a slotted Drum and FIG. 2 shows a section along the line 2-2 of FIG. I in the direction of the arrows seen.

In putting the invention into practice in the illustrated embodiment, a drum is divided into four compartments c in length, the compartments being held together by bolts or similar means between two end plates a and b . Each compartment c of the drum consists of a number of separate chambers d formed by a series of ribs e which radially connect the inner and outer walls of the drum. The separate compartments c of the full drum are combined in such a way that the ribs e are aligned so that the chambers d'extend over the entire length of the drum. Hollow bodies made of metal gauze or ceramic material are fitted into these chambers d in such a way that the cold air or the hot gas can flow from the inside to the outside of the drum or vice versa. The inner and outer walls of the drum are pierced by holes or slots f and g through which the hot gas or cold air can flow.

Assuming that the cold air is in one half of the drum flows from the inside to the outside, while in the other half of the Then drum the hot gases will flow from the outside to the inside the outer wall of the drum have a correspondingly higher temperature than the inner wall. This creates a tendency for the outer wall in relation to the inner wall in the To expand circumferential direction. This expansion of the outer wall in relation to the inner wall is made possible by slots h in the longitudinal direction in the Ribs e are provided. Because the outer wall of the drum forcibly by the ribs e is held, any excessive expansion of the outer wall tends to to close the gap of the slots h.

The compartments c are through a series of longitudinal bolts passing through the coldest wall, in the case in question the inner wall, the drum go, with the end plates attached. This will cause the bolts to move as a result of any Forgive temperature fluctuations as little as possible.

In operation, the outer walls tend to expand in a longitudinal direction in relation to the inner walls, and in order to allow little or no distortion of the end plates a and b , the compartments c of the drum are made in such a way that they have an intermediate gap i which is closed when the temperature of the outer wall of the drum reaches the operating temperature.

Claims (5)

PATENT CLAIMS: i. Circulating regenerative heat exchanger in the form of a cylindrical hollow drum for gas turbines, characterized in that the concentric inner and outer walls are connected by a number of radial, evenly spaced ribs (e) which divide the drum into a number of longitudinal chambers (d ) share. 2. Circulating heat exchanger according to claim i, characterized in that the inner and outer walls of the longitudinal chambers have holes or have slots (f, g) through which the hot gases and cold air flow. 3. Circulating heat exchanger according to claim i or 2, characterized in that that the longitudinal chambers (d) contain hollow bodies through which the hot gases and cold air Hindurrh flow and thereby the to be given off by the hot gases to the cold air Absorb heat. 4. Circulating heat exchanger according to claim i, 2 or 3, characterized characterized in that the drum is longitudinally divided into a plurality of annular compartments is divided, which are connected by bolts on their cold side while they are have an axial play on the hot side. 5. Circulating heat exchanger according to claim i, 2, 3 or 4, characterized in that the drum on its hot side has radial slots (h) in the ribs between the chambers.