RU2716640C1 - Silicone seals of high-temperature rotary disc heat exchanger - Google Patents

Abstract

FIELD: heating equipment.

SUBSTANCE: invention relates to heat engineering and can be used in regenerative rotating disc heat exchangers. In rotary disc heat exchanger in rotor to compensate for unavoidable thermal deformations there additionally are elastic silicone seals with siliconized pyrographite coating arranged on outer surface of discs on projection of gaps between hexagonal cups, wherein width in circumferential direction of labyrinth seals in housing is more than any size of hexagonal cell in same direction, and speed of mutual movement of seals is greater than rate of spurious flow of spills in gap between them.

EFFECT: higher efficiency of high-temperature rotary disk heat exchanger.

1 cl, 4 dwg

Description

Scope: thermal power engineering, mainly for gas turbine plants, for example, microturbines, mainly as part of a hybrid power plant for generating electric current. The inventive silicone seals of a high-temperature rotating disk heat exchanger and a method of their work to compensate and prevent thermal deformations of the frame of the rotating disk heat exchanger by manufacturing a cellular structure of the heat exchanger frame, where the cells are made in the form of separate glasses, and the heat exchanger disks are made of materials having different temperature coefficients extensions, and additional silicone seals.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see RF patent No. 20055960, applicant GAZ Production Association (Gorky Automobile Plant), Convention priority 26.05.1992 RU 92 5055034.

The main disadvantage of the known heat exchanger for preventing and compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is the use of a frame with different stiffness and heat capacity, while the authors argue that this should lead to a convergence of temperatures of cold and hot end disks. This statement is controversial, since the stepped design of the casing and the conical shape of the heat transfer elements cannot guarantee the heat transfer from gas to air through the intermediate solid heat carrier of the frame of the heat transfer elements necessary for temperature equalization, because its heat capacity and transmission intensity cannot guarantee gas cooling and heating of the air to the same or close in temperature value, because in this case the temperature difference between the gas, air and intermediate solid t plonositelem and efficacy of their temperature equalization on the end disk in time quickly and dynamically reduced accordingly change the frame shape and giving it due to thermal deformation mushroom shape can not be avoided.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see USSR copyright certificate No. 1345015, authors L.Ya. Eremenko and V.I. Grishin, publ. 10/15/87).

The main disadvantage of the known heat exchanger for compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is the possibility of adapting the separating working seals to the mushroom-shaped frame of the rotating disk regenerator of radial seals of the gas and air flow separator, which is not very effective even when trying to automatically adapt due to wear seals and mushroom-shaped working surfaces of hot and cold drives.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see USSR copyright certificate No. 580410, inventors V.I. Grishin, V.S. Nazarenko, T.S. Dobryakov, S.Ya. Mikhailov and E.I. Socks, publ. 11/3/07).

The main disadvantage of the known heat exchanger for compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is the possibility of adapting the separating working seals to the mushroom-shaped frame of the rotating disk regenerator for side seals of the gas and air flow separator, which is not very effective due to the rapid wear of the seals and side the surface of the frame, hot and cold disks in their working deformed state.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see USSR author's certificate No. 208162, applicant Podolsky Machine-Building Plant named after Sergo Ordzhonikidze, publ. 12/29/67).

The main disadvantage of the known heat exchanger for compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is the possibility of adapting to the mushroom shape of the rotary disk regenerator frame and the adaptive control mechanism of the working radial seals of the gas and air flow separator, which is not very effective for constant wear of seals and surfaces of hot and cold dis forged in a deformed working condition, regardless of the shape of the heat exchanger and seals to it due to their thermal deformation.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see RF patent No.RU 2441188, applicant BALKE-DURR GMBH (DE), publ. 01/27/2012.).

The main disadvantage of the known heat exchanger and compensation of its mushroom-like deformation during operation of a high-temperature rotating disk heat exchanger during its operation is a complex sequence of actions and a complex mechanism for controlling them when trying to create a non-contact seal and maintain an optimal clearance in the seal using temperature-controlled complex rod mechanisms located along all seal surfaces.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see USSR copyright certificate No. SU 613193 A1, authors Markman Yakov Abramovich, Gerashchenko Boris Avksentievich, Borodyansky Moisei Evseevich, Ushakov Ivan Kirillovich, Vainshtein Leonid Petrovich, publ. 10/27/2011.)

The main disadvantage of the known heat exchanger for compensating for the mushroom-like deformation of a high-temperature rotating disk heat exchanger and the follower mechanism used to maintain gaps in the seals during its operation is a complicated sequence of actions when trying to create an almost non-contact seal and maintain an optimal minimum clearance along the entire length of the seals using temperature-controlled, complex, adjustable tracking mechanisms located on all seal surfaces that does not allow to achieve the optimal minimum clearance along the entire length of the seals due to the constant uneven wear of the seal plates in the mushroom-shaped deformed working condition of the frame, wear of the rollers and cams that make up the follower mechanism, and this, respectively, which will lead to uncontrolled contact of the seals and malfunction of the seals during thermal deformation of the rotor.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see patent for the invention of the Russian Federation No. 2432540, the applicant BALKE-DURR GMBH (DE), publ. 10/27/2011.)

The main disadvantage of the known heat exchanger for compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is the complicated sequence of actions when trying to create a non-contact seal and maintain a removable flow rate of the flowing components of the air and gas flows through the optimal clearance in the seal by aspirating the air and / or gas of the leak components, in the area of seals located on all surfaces, mainly in the radial direction, p allowing to stabilize the distribution of air and gas flows and their temperatures on the surface of the frame, which should reduce mushroom-like deformations, but this is problematic.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see Patent for the invention of the Russian Federation No.RU 2119127 C1, Applicantbau Rotemole Brandt und Kritzler GmbH (DE), publ. 09/20/1998.)

The main disadvantage of the known heat exchanger for compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is the complicated sequence of actions and adjustable seals when trying to create a non-contact seal and maintain the separation of air and gas cavities through the optimal clearance in the seal using a flow of separation gas that compensates and prevents air overflow and gas, while circumferential and radial seals form surfaces equations located in the common plane and seamlessly turning into each other at the joints and with the possibility of automatically maintaining a gapless contact, and supplying a shut-off gas to the seal gaps, which, in the author's opinion, stabilize the temperature distribution and the constancy of the gaps on the frame surface, which under thermal mushroom conditions deformation of the frame will violate the contact conditions and the rapid wear of the contact surfaces of the seals and frame.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see USSR copyright certificate No. 881517, applicant Gorky Automobile Plant (Production Association "GAZ"), publ. 11/15/1981).

The main disadvantage of the known heat exchanger for compensating for the deformation of a high-temperature rotating disk heat exchanger during its operation is that in the event of thermal deformations (see Fig. 1 of the USSR copyright certificate No. 881517) of the rotor 6, its mushroom-like warping is eliminated by strict fixation of the rotor 6 relative to the housing 1 using the interaction of the ring 14 with the annular groove 13 through the anti-friction linings 15. Thus, according to the applicant, the skew of the rotor sealing surfaces is eliminated 6, which eliminates the opening of gaps between these surfaces and seals 9 and 10 and thereby reduces the flow of heat-exchanging media - air and gas. The mechanical alignment of the mushroom-shaped shape of the heat transfer surface of the rotor frame cannot be fully compensated, for example, due to the presence of technological gaps in the joints, which will lead to distortion and rapid wear of the contacting surfaces of the heat exchanger frame, its seals and, accordingly, malfunction of the seals.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see USSR copyright certificate No. SU 800579 A1, applicant Gorky Automobile Plant (Production Association GAZ), publ. 01/30/1981)

According to the applicant, the execution on the hot side of the frame of the transverse channels communicated by the inlet openings with the air inlet pipe and the output holes with the air outlet pipe allows for cooling the end of the frame on the hot side, to reduce warpage of the frame by equalizing the temperature of the surface of the frame and to increase the reliability of the regenerator. But at the same time, the applicant does not take into account the possibility of mushroom warping of the entire rigid frame, consisting of monolithic hexagonal cells, in which heat transfer elements are installed in the form of conical inserts, which are constantly washed alternately on one side with cold air heated by them, and on the other with hot gases, as a result of which thermal mushroom-like deformations of the frame under their influence cannot be fully compensated by smaller deformations of the cooled hot disk. But this is not enough to eliminate the mushroom-shaped frame shape and will not allow completely eliminating the thermal mushroom-shaped deformation of the heat exchanger frame, because uneven heating of the rigid frame along the length of each channel of heat-exchange cells with different temperatures with the achievement of different temperatures at their hot and cold ends will create different values of the radial expansion of the hard the frame, which will lead to the appearance of mushroom-shaped thermal deformation of the rigid frame and will lead to rapid wear of the seals and contact surfaces of the frame with it. Cooling a hot disk can only partially reduce the fungus-like thermal deformation of a rigid frame.

Known high-temperature rotating disk heat exchanger containing a housing with inlet and outlet air nozzles and with inlet and outlet gas nozzles and a rotor installed therein, comprising a frame consisting of cold and hot end disks and heat exchanger cells installed in the heat exchanger housing with rotation and alternating communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchange The ennik is configured to communicate in countercurrent, respectively, from the side of the hot disk with the gas inlet and outlet air pipe, and from the side of the cold disk with the gas outlet and air inlet pipe, the gas and air pipes of the housing communicating with each other through the respective disks and heat exchange channels cells and are separated by hot and cold disks by radial and circumferential seals placed on the housing (see RF patent No. RU 2623133 C1, applicant Federal State Budgetary Educational Institution of Higher Education "Moscow Polytechnic University" (RU), publ. 01/27/2012.)

According to the applicant, the execution on the hot side of the frame and around the heat-exchange cells of the transverse cooling channels communicated by the inlet openings with the air inlet pipe and the output holes with the air outlet pipe allows cooling the end of the frame on the hot side and the frame with heat-exchange cells, to reduce warpage of the frame due to leveling the temperature of the surface of the disk and the cells of the frame and increase the reliability of the regenerator. But at the same time, the applicant does not take into account the possibility of mushroom warping of the entire rigid frame, consisting of monolithic hexagonal cells, in which heat-transfer elements are installed in the form of inserts that are constantly washed on the one hand by the cold air heated by them, and on the other, by hot gases and, at the same time, heat-exchange cells in the form of heat transfer packages are rigidly connected to the walls of the frame and do not have thermal insulation from the cooled channels, as a result of which thermal deformations of the frame and its constant heating from heat-exchange cells under such their influence cannot be compensated by smaller deformations of the cooled hot disk and the walls of the cells of the frame, and cooling will not be able to maintain the frame in the undeformed state of its cylindrical shape, since the outer walls of the cells of the frame are not thermally insulated from their inner part and are rigidly connected to it , for this reason, the real state and deformations of the frame are determined by heating from heat of heat transferring packets and their mechanical deformation effect on the frame and deformations of the frame Kasa due to the uneven radial distribution of temperatures on the supporting structures of the frame.

The closest technical solution is the device of a rotating disk regenerator, according to the patent of the Russian Federation No.RU 2623133 C1, which is closest to the invention according to the problem being solved and has the greatest number of actions coinciding with the actions according to the invention.

The technical task of the proposed invention is to improve the operability of a high-temperature rotating disk heat exchanger by preventing deformation of its cylindrical shape under the influence of a constantly acting and changing temperature field acting on the rotating disk heat exchanger, by maintaining the cylindrical shape of the frame of a high-temperature rotating disk heat exchanger, eliminating the possibility of a deforming effect on the frame of unevenly heated heat exchange cells and improve the performance of the seals by installing additional silicone seals of a high-temperature rotating disk heat exchanger.

When implementing the sequence of actions corresponding to the operation of the heat exchanger, the technical task is solved and the following technical results are described, which are described below.

The technical problem is solved in that the technical results are realized during the operation of the heat exchanger in the following sequence of actions, which helps prevent deformation of the shape of a high-temperature rotating disk heat exchanger, which contains a housing with inlet and outlet air pipes and with inlet and outlet gas pipes and a rotor installed in it, including a frame consisting of cold and hot end disks and heat exchanger cells, mounted in the heat exchanger housing with rotation I and alternate communication through its heat-exchange cells in countercurrent flow, respectively, of the inlet and outlet air and inlet and outlet gas pipes, and the disk heat exchanger is configured to communicate in counterflow, respectively, from the side of the hot disk with the inlet gas pipe and the output air pipe, and from the cold disk - with an outlet gas and inlet air pipe, the gas and air pipes of the housing communicating with each other through the respective disks and channels of the heat exchange cells and are separated by hot and cold disks with corresponding radial and circumferential seals placed on the housing.

Moreover, the radial seal is usually located in the diametrical plane of the cross section of the corresponding disk between the air and gas flows, and the circumferential seal of the rotor is placed around the circumference of the corresponding disk, and the radial and circumferential rotor seals on the housing are labyrinthine. If necessary, additional seals can be installed on the side surface of the rotor, for example, to separate aggressive media and prevent their entry into the internal channels of the rotor frame. These features almost completely repeat the set, properties and well-known technical results achieved in the prototype during operation of its heat exchanger, consisting in reducing leaks and flows and in aligning the temperature field along the surfaces of hot and cold disks, which can reduce the extreme values of thermal deformations and increase the uniformity of their distribution on the indicated surfaces. Improving the quality of work of a high-temperature rotating disk heat exchanger is achieved by the efficient operation of seals and high quality separation of air and gas flows. First of all, regardless of the type and design of the seals, their quality of work is characterized by the stability of the position and the absence of changes in the shape of the seals in this process, which is determined during operation by the constancy of the working gap between the housing and the rotor, the main premise of which is the constancy of the shape of the rotor, which does not should depend on changes in the distribution of the temperature field over the surface of the cold and hot end disks and the thermal state of the frame and heat transfer cells.

To reduce the deforming effect of temperature differences on the frame and reduce the magnitude of its thermal deformations without the need to create complex conditions and structures for aligning and stabilizing the temperature field along the supporting elements of the frame structure during its operation, it is necessary to change the frame structure and the sequence of actions during its operation, leading to a decrease deformations of the shape of the frame. This is achieved through the use of the following distinctive features of the proposed heat exchanger.

1. Radial and circumferential rotor seals on the housing are labyrinthic, which reduces the possibility of air and gas leakage between the air and gas circuits during their countercurrent movement and eliminates their negative effect on the thermal state of the frame.

2. The rotor is additionally equipped with elastic silicone seals coated with siliconized pyrographite, placed on the outer surface of the disks according to the projection of the gaps between the hexagonal cups, and the width in the circumferential direction of the labyrinth seals in the housing is greater than any size of the hexagonal cell of the silicone seal in the same direction,

3. Cold and hot end disks are made of materials, the ratio of linear expansion coefficients of which is inversely proportional to the ratio of the growth of average working temperatures of the disks, which eliminates the uneven thermal expansion of the disks under the influence of different working temperatures.

4. The implementation of the heat-exchange cells in the form of glasses with external hexagonal surfaces and with internal channels and installing them between the end disks with at least one hard mount point on each disk, and at least the location of each two hard mount points of the glasses on adjacent disks in the diametrical plane of the section of their base of the glasses, the location of these points in the radial and / or tangential plane plane of the section of the disks passing through the axis of symmetry of each glass.

5. The choice of the gap between the glasses from the condition of achieving the possibility of their free mutual expansion at the maximum working temperature eliminates the influence of uneven heating along the length of the channel and the corresponding uneven linear radial expansion of the walls of the glass, and exclude the effect of its mushroom shape on the shape of the frame heat exchanger.

Consider these features and the technical results that occur during operation of a high-temperature rotating disk heat exchanger.

By controlling the flow and temperature of the flows, the temperature and flow control system of air and gas flows, used mainly as a part of hybrid power plants to generate electric current, to ensure the correct operation of the high-temperature rotating disk heat exchanger, the flows on the hot part of the rotor are close or with a minimum possible temperature difference accordingly, at the exit from the hot end disk of the rotor carcass of the outgoing first heated air about the volumetric flow and the second gas volumetric flow entering the rotor through the second hot end disk of the rotor carcass in the area of the radial and circumferential rotor seals mounted on the housing and made labyrinth. On a cold disk, the uniformity of the temperature field will be maintained automatically due to heat transfer and alternately heating and cooling glasses of heat-exchange cells and disks. This allows you to create a more uniform temperature field on the surfaces of the hot and cold disks and is obvious, since these actions are similar to the design features and known actions during the operation of the prototype and are the development of these known actions, because at close temperatures and thermophysical properties of the heat exchange cells absorbed and sent back heat should create conditions for creating a uniform field of close temperatures on the surface of hot and cold disks. There can be absolutely no identical temperatures on these surfaces due to the fact that heat transfer with the necessary intensity occurs only with a sufficient temperature difference between air or gas and the heat transfer material of each cell. This obtaining of the constancy of the temperature field is possible due to the possibility of the gas turbine hybrid installation operating in one optimal selected turbine operating mode and the operation of the flow rate and temperature control system and its regulation of temperature and air and gas flow rates. It should be noted that the uniformity of the temperature distribution over the hot and cold disks can be correctly organized by choosing the thermophysical characteristics of the heat exchange cells and the heat transfer (contact) time, the higher their efficiency, the closer the initial and final temperatures of the surfaces of the hot and cold disks, respectively, for the first heated air volumetric flow and, accordingly, the second cooled gas volumetric flow, since the incoming first air volumetric flow in is put into the rotor through the first cold end disk of the rotor carcass, and leaves it through the second hot end disk of the rotor carcass in the form of an outgoing first heated air volume flow, and the second gas volume flow enters the rotor through the second hot end disk of the rotor carcass and exits through the first cold end disk of the rotor carcass in the form of an outgoing second cooled gas volumetric flow, the more heat these flows give and receive from heat transfer cells, the closer the air and gas temperatures in part x flows passing through the hot and cold end disks of the frame. The higher the uniformity of the temperature distribution across the disks, the less linear the unevenness, along the axis of the canal channels the changes in their length and the less deformation of the disks arising from this. And accordingly, it is possible to maintain a smaller gap in the labyrinth seals and reduce the leakage between air and gas flows.

In the rotor, there are additionally installed elastic silicone seals coated with siliconized pyrographite, placed on the outer surface of the disks according to the projection of the gaps between the hexagonal cups, and the width in the circumferential direction of the labyrinth seals in the housing is greater than any size of the hexagonal cell of the silicone seals in the same direction. The preservation of the elasticity of silicone, its heat resistance and stabilization of properties are determined by penetration into the colder part of the disks and the heat-dissipating and thermostabilizing ability of the inner hexagonal surface of the glasses adjacent to it. In case of urgent need, the internal gaps between the glasses can be further cooled by known means and methods. It should be noted that the inner channel of each glass can be filled with any heat-accumulating composition, and its density and porosity is determined by the optimal ratio of aerohydraulic resistance and heat-absorbing properties of the material of the filler composition. In this case, parasitic pore volumes can be selected from the condition of minimal mutual transfer of air and gas. If necessary, these spaces under the labyrinth seals can be purged with inert gas, air or gas, which will prevent air or gas from entering the adjacent stream.

The execution of cold and hot end disks of materials, the ratio of the linear expansion coefficients of materials of which is inversely proportional to the ratio of the increments in the average working temperature of the disks. In this case, the heat exchange cells are made in the form of cups with external hexagonal surfaces and with internal channels and are installed between the end disks with at least one hard mount point on each disc, each two hard mount cup points on adjacent disks are placed in the diametrical plane of their cross section bases located in a radial and / or tangential to it plane of section of the disks passing through the axis of symmetry of each glass, and the gap between the glasses is chosen with the possibility of their free th mutual radial expansion at the maximum operating temperature. These features make it possible to obtain the same linear expansion of the hot disk at high working temperature at the same (as in analogues and prototype) temperatures on the surfaces of the hot and cold disks due to the low coefficient of linear expansion of its material and relatively large linear expansion of the cold disk with a higher coefficient of linear expansion material at a lower temperature. With the right choice of the linear expansion coefficients of the materials of the cold and hot end disks, it is inversely proportional to the ratio of the growths of the average working temperatures of the disks, their absolute linear increase in sizes at the calculated or selected working temperatures will be almost the same, and the overall mushroom-like deformations of the frame will be minimal. By increasing the average operating temperature of the disks, the differences of the corresponding absolute operating temperatures are selected minus the absolute initial temperature of the inoperative initial state of the frame.

If the heat-exchange cells are made in the form of cups with external hexagonal surfaces and with channels and they are installed between the end disks with at least one hard mount point on each disc, and at least every two hard mount points of the cups on adjacent disks are located the diametric plane of the cross section of their bases, located in the radial and / or tangential to it plane of the cross section of the corresponding disk, passing through the axis of symmetry of each glass, this eliminates action of thermal deformations of cells on end discs at a very significant temperature drop along the length of each cell, as the cup end surfaces which are in contact with the respective disk are free to linear expansion and that does not cause deformation of the disks mushroom. The location of the points of rigid attachment of the glasses of the heat-exchange cells on adjacent disks from the side of the hexagonal surface of the glasses in the diametrical plane of the section of their bases located in the radial plane of the section of the disks, that is, in the plane passing through the axis of their rotation in the radial direction, allows to achieve a minimum temperature difference between the indicated points, since these points simultaneously begin to be exposed to the corresponding flow of air or gas and will be at close temperatures conditions under the entire process of periodic heat transfer, even if they will be on the same disk. The location of the points of rigid attachment of the glasses of heat-exchange cells on adjacent disks in the diametrical plane of the cross section of their bases, located tangential to the radial plane of the cross section of the disks, allows you to achieve a given temperature difference between these points, since these points are located in close or identical conditions of exposure to the corresponding air flow or gas for the selected inner surface of the channel of each heat exchange cell and will be in close to the differential temperature conditions in those The whole process of heat transfer, because part of the air flow or gas located in the specified channel of the heat exchange cell will have almost the same temperature distribution along the length of the channel, as a result of which deformations of the shape of each cell individually and of all cells together will not lead to a change in the shape of the frame, but will cause only the corresponding rotation in the tangential direction of the points of rigid fastening of one end disk relative to another. Deformations of the position and bends of the disk shape due to changes in the length of heat-exchange cells will not be significant, since the temperature distribution gradient along the length of the glasses will not change sign, and the average temperature of the hexagonal surface of the glasses of the frame and the massive part of the glass during the cycle will vary slightly, and temperature differences on the working surface of the channels of the glasses will lead to a direct () or reverse) (barrel-shaped form of change in their walls, which with a sufficient mass of the glass will slightly affect its working length.

In this case, the movement of air and gas flows with similar temperatures in the area of the radial and circumferential seals of the rotor of the rotary disk heat exchanger installed on the casing, and the performance of these seals are labyrinth, under the above conditions, allows to achieve a minimum clearance and a high effective non-contact seal.

The gaps between the hexagonal walls of the glasses of the frame of the rotating disk heat exchanger, which are selected from the condition of providing free mutual radial expansion from the axis of symmetry of each glass relative to the others at its maximum working temperature without mutual contact and the possibility of deformation of the frame, this design eliminates deformation from uneven heating surfaces of disks and massive parts of glasses.

The proposal is illustrated by drawings, which show:

In FIG. 1 shows a partial section through the frame of a heat exchanger along one heat exchanger cell, along labyrinth seals on the housing and along silicone seals on the rotor, which are shown conditionally on one side of the rotor;

In FIG. 2 is a perspective view of a schematic view of a heat exchanger frame with a set of seals and a partial section.

In FIG. Figure 3 shows the location of the silicone seals along the projections of the gaps between the hexagonal surfaces of the glasses.

In FIG. 4 shows a diagram of a hybrid power plant for generating electric current and an approximate temperature distribution of air and gas flows in it.

Silicone seals of a high-temperature rotating disk heat exchanger, which contains a housing with inlet and outlet air pipes and with gas inlet and outlet pipes and a rotor installed in it, including (see Fig. 1, 2 and 3) frame 1, consisting of hot 2 and cold 3 end disks and heat exchange cells 4, mounted in the housing of the heat exchanger with the possibility of rotation and alternate communication through its heat exchange cells in countercurrent flow, respectively, of the input and output air and input and output gas pipes of the housing, and the disk heat exchanger is configured to communicate in countercurrent, respectively, from the side of the hot disk 2 with an inlet gas pipe and an outlet air pipe, and from the side of the cold disk with a third output gas and air pipe, and the gas and air pipes of the housing are communicated between each other through the respective disks 2 or 3 and the channels of the glasses of the heat-exchange cells 4 and are divided into hot and cold disks by the corresponding radial 5 and circumferential 6 seals, placed mi on the case, with radial 5 and circumferential 6 rotor seals installed on the case and made of labyrinths, and in the rotor additionally installed elastic silicone seals 7 with a coating of 8 siliconized pyrographite placed on the outer surface of the disks 2 and 3 according to the projection of the gaps 9 between the hexagonal cups moreover, the circumferential width of the labyrinth seals in the housing is greater than any size of the hexagonal cell of the silicone seal in the same direction. Cold 2 and hot 3 end disks are made of materials, the ratio of the linear expansion coefficients of which is made inversely proportional to the growth rate of the average working temperatures of the end disks 2 and 3. The heat exchange cells 4 are made in the form of cups with external hexagonal surfaces and with internal channels and are installed between the end disks 2 and 3, with at least one hard mount point 10 on each disk, and at least every two hard mount points of glasses on adjacent disks are located in the diametral plane of the cross section of their bases, located in the radial and / or tangential plane of the cross section of the disks 2 or 3 passing through the axis of symmetry of each cup, and the gap 9 between the hexagonal surfaces of the cups of the heat exchange cells 4 is selected from the condition of achieving the possibility of their free mutual expansion at maximum working temperature.

In FIG. 2, the gas flow is shown blackened by the arrow, and the air flow from the hot disk 2 by the white arrow. The glasses of heat-exchange cells 4 are rigidly fixed to the disks 2 and 3 at the attachment points 10 with the possibility of formation of gaps between them 9, which are selected from the condition of free radial mutual expansion glasses from their axes is possibly symmetric, since the real value of the displacement of the glass relative to the axis depends on the places of rigid fastening of the glass. So, for example, with a radially pairwise rigid attachment of the glass to each disk, due to the difference in the expansion coefficients of the glasses and disks, the shape of the glass will be ovalized and local deformation will change the shape of the holes, and disks 2 and 3 will not change their overall shape, because with a sufficient length glasses of the frame 1 they do not affect their separate cups of the heat-exchange cell 4 under the action of their own and discs and it can slightly bend, not significantly affecting the cylindrical shape of the entire frame. The location of at least two points of rigid attachment of the glasses of the heat-exchange cells 4 on adjacent disks 2 and 3 in the diametrical plane of the section of the bases of the glasses 4 of the heat-exchange cells located in the tangential plane of the section of the disks 2 and 3, i.e. in the plane perpendicular to the radial plane of the cross section, it is possible to achieve a minimum temperature difference between the indicated points, since these points are located in close or identical conditions of exposure to air or gas for the selected working surface of each heat exchange cell and will be in relatively close temperature conditions during the entire heat transfer process , because part of the flow of air or gas located in the specified channel of the heat exchange cell 4 will have almost the same distribution temperature along the length of the inner channel of its glass, as a result of which thermal deformations of the linear dimensions and shape of each cell separately and of all cells together will not lead to a change in the cylindrical shape of the frame, but will only cause their centrally symmetrical arrangement relative to the axis of rotation of the frame 1 corresponding rotation of one of the end disk relative to another or the average temperature of the hexagonal surface of the glasses of the heat transfer cells of the frame due to the massiveness of the heat exchange part of the glasses and the edge of the heat transfer cycle will change insignificantly, temperature drops on the working surface of the channel and the hexagonal surface of the glasses will lead to a direct () or reverse) (barrel-shaped form of change in their walls, which, if the mass of the glass is sufficient, will slightly affect its working length. With pairwise opposing arrangement of points of rigid attachment of the glasses, there will be no rotation, and only a slight deformation of the glasses is possible 4.

A high-temperature rotary disk heat exchanger to prevent deformation of the frame of a high-temperature rotary disk heat exchanger for a hybrid power plant is implemented using the above-mentioned device of a high-temperature rotary disk heat exchanger and silicone seals in it and the following sequence of actions during its operation and reaches the specified technical results and the solution of the technical task.

In FIG. 4 shows a hybrid microturbine installation and an approximate temperature distribution therein. A high-temperature rotating disk heat exchanger is designed for a hybrid power plant, used mainly as a part of hybrid power plants to generate electric current, usually including a temperature and air flow rate control system that works as follows: after starting and entering the operating mode through the air filter, air enters the compressor, where it is precompressed and enters the recuperator or regenerator, which is more preferable m for microturbine installations, in the form of an incident first air volumetric flow that enters the rotor of the regenerative heat exchanger from its cold side 11 through the first cold end disk 3 of the frame 1 of the rotor, and leaves it through the second hot 2 end disk of the frame 1 of the rotor to its hot side 12 in the form of an outgoing first heated air volumetric flow that enters the microturbine engine, the temperature of the gases at its outlet is regulated by a control system, for example, by changing the supply The number of fuel into the combustion chamber. After that, the second gas volume flow enters the rotor of the regenerative heat exchanger from the hot side 12 through the second hot end disk 2 of the rotor frame 1 and exits through the first cold end disk 3 of the rotor frame 1 in the form of a second cooled gas volumetric rotary disk heat exchanger leaving the cold side 11 .

In this case, the silicone seals of the high-temperature rotating disk heat exchanger are realized, implemented in the sequence of actions of its operation with the possibility of preventing the deformation of the frame shape of the high-temperature rotating disk heat exchanger for a hybrid power plant, intended for use mainly in hybrid power plants for generating electric current, usually including a control system temperatures and air and gas flow rates c, a housing and a rotor installed therein, comprising a frame 1, consisting of cold 3 and hot 2 end disks and heat exchange cells 4 in the form of hexagonal cups, mounted in the heat exchanger housing with the possibility of rotation and alternating passage through it in countercurrent, at least one first heated air volumetric flow and at least one second cooled gas volumetric stream, and the incident first air volumetric stream enters the rotor through the first cold end disk 3 of the frame 1 rotor, and leaves it through the second hot end disk 2 of the frame 1 of the rotor in the form of an outgoing first heated air volumetric flow, and the second gas volume stream enters the rotor from the hot side 12 through the second hot end disk 2 of the frame 1 of the rotor and exits through the first cold the end disk 3 of the rotor cage on the cold side 11 in the form of an outgoing second cooled gas volume stream, while the first air and second gas volume flows are separated on the rotor from each outer side of the hot and cold disks osredstvom, at least one radial circumferential 5 and 6 of the rotor seal disposed on the housing (which in Fig. 1, 2 and 3 not shown). These features completely repeat the combination, properties and well-known technical results achieved in the prototype, which consist in leveling the temperature field to maintain a flat shape on the contact surfaces of the hot and cold disks of the rotor frame, which can reduce the extreme values of thermal deformations and increase the uniformity of their distribution over these surfaces.

To reduce the deforming effect of temperature extremes on the frame 1 and to reduce the values of its thermal deformations without complicated creation of a cooling structure and conditions for leveling and stabilizing the temperature field along the load-bearing structural members of the frame 1, it is necessary to change the design of the frame 1 and sequential actions with it, leading to a decrease in the frame deformations . This is achieved through the use of the following distinctive features of the proposed heat exchanger.

At the same time, by regulating the flow rates and flow temperatures, a system (which is not shown in Fig. 4) controlling the temperatures and flow rates of air and gas flows according to the temperature sensor readings supports streams that are close or with a minimum temperature difference on the hot side 12 of the rotor at the outlet of the outgoing first heated air volume flow and the second gas volume flow entering the rotor through the second hot end disk 2 of the rotor frame 1 in the zone of the rotor radial seals 5 mounted on the housing s labyrinth.

In the rotor, there are additionally installed elastic silicone seals 7 with a coating of 8 siliconized pyrographite placed on the outer surface of the disks (see Fig. 3) along the projection of the gaps 9 between the hexagonal cups, and the circumferential width of the radial labyrinth seals in the housing is larger than any size of the hexagonal cell silicone seals in the same direction

The systems for controlling the temperatures and flow rates of air and gas flows used primarily as part of hybrid power plants for generating electric current are diverse and consist of well-known control devices, which cannot be the subject of the proposed invention. This allows the well-known methods and using publicly available technical means to create a more uniform temperature field on the surfaces of the hot and cold disks, which is obvious, since these actions are similar to the known actions in the prototype and are the development of these known actions. This is possible due to the possibility of operation of a gas turbine hybrid installation in one optimal selected operating mode of a microturbine engine. It should be noted that the uniformity of the temperature distribution over the hot 2 and cold 3 disks can be correctly organized by choosing the thermophysical characteristics of the heat exchange cells and the heat transfer (contact) time, the higher their efficiency, the closer the initial and final temperatures of the surfaces of the hot and cold disks respectively, for the first heated air volumetric flow and, accordingly, the second cooled gas volumetric flow, since the incident first air volumetric flow enters the rotor through the first cold end disk 3 of the frame 1 of the rotor, and leaves it through the second hot end disk 2 of the frame 1 of the rotor in the form of an outgoing first heated air volume flow, and the second gas volume stream enters the rotor through the second hot end disk 2 of the frame 1 of the rotor and leaves through the first cold end disk 3 of the frame 1 of the rotor in the form of an outgoing second cooled gas volumetric flow, as a result of which these flows give more and receive heat from heat transfer cells, and accordingly closer will be the air and gas temperatures in the parts of the flows passing respectively through the hot 2 and cold 3 end disks of the frame 1.

With the right choice of the ratio of linear expansion coefficients of materials of hot 2 and cold 3 end disks, which is chosen inversely proportional to the ratio of the growth of average working temperatures of the disks, while the heat transfer cells 4 are made in the form of cups with external hexagonal surfaces and with internal channels and are installed between the end disks with at least one hard-mount point on each disk, and at least every two hard-mount points of glasses on adjacent disks gayut a diametral sectional plane of their bases arranged in a radial and / or tangential thereto disks sectional plane passing through the axis of symmetry of each cup, and the gap between the glasses are selected to allow their free relative expansion at the maximum operating temperature. These signs make it possible to obtain the same linear expansion of the disks at the same (as in the analogues and prototype) temperatures on the surfaces of the hot and cold disks, correspondingly small for a higher working temperature of the hot disk, i.e. at high working temperature due to the small coefficient of linear expansion of its material it will be relatively low linear expansion, and at a lower operating temperature, relatively large linear expansion of the cold disk with a higher coefficient of linear expansion of the mat rial, which as a result of the impact of different temperature values will lead to almost the same linear expansion of the hot and cold respectively, to drive them to the selected or calculated operating temperature. With the correct choice of the linear expansion coefficients of the materials of the cold and hot end disks, they are inversely proportional to the ratio of the increase in the working temperature of the disks, their absolute linear increase in size at the calculated or working temperatures selected experimentally will be almost the same, and the general mushroom-like deformations of the frame 1 will be minimal.

If the heat transfer cells 4 are made in the form of cups with hexagonal surfaces and an internal channel and are installed between the end disks 2 and 3, with at least one hard mount point 10 on each disc, and at least every two hard mount points 10 of the cup neighboring disks are placed in the diametrical plane of the cross section of their bases, located in the radial and / or tangential plane of the cross section of the disks and passing through the axis of symmetry of each glass, this eliminates the effect of heat new deformations of the heat exchange cells 4, made in the form of glasses, to the end disks at a very significant temperature difference along the length of each heat exchanger cell 4, since the end surfaces in contact with the corresponding disk have the possibility of free linear expansion and this does not cause deformation of the disks. The location of the points of rigid attachment of the glasses of heat-exchange cells on adjacent disks in the diametrical plane of the cross section of their bases, located in the radial plane of the cross section of the disks, i.e. in the plane passing through the axis of rotation of the disk in the radial direction, it is possible to achieve a minimum temperature difference between the indicated points, since these points simultaneously begin to be exposed to air or gas and will be at close temperature conditions during the entire heat transfer process, even if they are on single drive. The location of the points of rigid attachment of the glasses of the heat-exchange cells 4 on adjacent disks in the diametrical plane of the section of their bases of the heat-exchange cells 4 located in the tangential plane of the section of the disks, i.e. in the plane perpendicular to the radial plane of its cross section in one direction, it allows to achieve a minimum temperature difference between these points, since these points are located in close or identical conditions of exposure to air or gas for the selected inner surface of each heat exchange cell and will be in relatively close temperature conditions in during the entire heat transfer process, because the part of the air or gas stream located in the specified channel of the heat exchange cell will have practical the same temperature distribution along the length of the channel, as a result of which thermal deformations of the linear dimensions and shape of each cell separately and of all cells together will not lead to a change in the cylindrical shape of the frame with obtaining a mushroom-like deformation, but will only cause a corresponding rotation of one end disk relative to another and possibly small bend.

The hexagonal shape of the outer surface of the glasses of the heat-exchange cells 4 is selected to simplify the selection and control of the gaps between them and their "tight packing" (optimal distribution over the cross section of the end disks of the frame).

In this case, the movement of air and gas flows with similar temperatures in the area of the radial seals of the rotor of the rotating disk heat exchanger on the casing and performing their labyrinth seals and the installation of additional silicone seals on the rotor, under the above conditions, allows to achieve a minimum clearance and a highly effective non-contact seal.

The performance of all the gaps 9 between the glasses of the frame of the rotating disk heat exchanger on each of the six outer faces of the glass, which are selected from the condition of the possibility of ensuring free mutual radial expansion of each glass in the direction of the selected face and its possible rotation around the axis of the glass, relative to other glasses of the frame with its maximum working temperature without the possibility of their mutual contact and the appearance of the possibility of obtaining deformation of the frame.

To reduce the possible leakage of air and gas, the technological installation gaps between the cups and discs can be sealed in any known manner using known means and using known heat-resistant sealing compounds, allowing mutual linear normal and tangential displacements of these parts within the selected or calculated gaps.

Based on the foregoing, we can state the following.

The stated technical problem is solved by technical means and can be used in the proposed form in the national economy, therefore, the proposal meets the criteria of the invention of "industrial applicability".

The proposal has differences from the design and operation of the known heat exchanger, therefore, meets the criteria of the invention of "novelty."

The proposal, when performing all known and new design features and the sequence of actions during operation of the heat exchanger, allows to achieve new previously unknown technical results, therefore, meets the criteria of the invention "inventive step".

Claims (1)

Silicone seals of a high-temperature rotating disk heat exchanger, which contains a housing with inlet and outlet air pipes and gas inlet and outlet pipes and a rotor installed in it, including a frame consisting of cold and hot end disks and heat exchanger cells with an internal channel installed in the heat exchanger body with the possibility of rotation and alternate communication through its heat exchange cells in countercurrent flow, respectively, of the input and output air and input and output gas nozzles, moreover, the disk heat exchanger is configured to communicate in counterflow, respectively, from the side of the hot disk with the inlet gas pipe and the outlet air pipe, and from the side of the cold disk with the outlet gas and air pipe, the gas and air pipes of the housing are interconnected through the respective disks and channels of the heat-exchange cells and are divided into hot and cold disks by corresponding radial and circumferential seals placed on the housing, distinguishing the fact that the radial and circumferential seals of the rotor on the casing are labyrinth, and the rotor additionally has elastic silicone seals coated with siliconized pyrographite placed on the outer surface of the disks according to the projection of the gaps between the hexagonal cups, and the width in the circumferential direction of the labyrinth seals in the casing is greater any size of the hexagonal cell of the silicone seal in the same direction, the cold and hot end disks are made of materials, the ratio of the coefficients l slightly expanding which is inversely proportional to the ratio of the increments of the average operating temperatures of the disks, the heat exchange cells are made in the form of cups with external hexagonal surfaces and with internal channels and are installed between the end disks with at least one hard-mounting point on each disk, and at least every two points of rigid attachment of glasses on adjacent disks are located in the diametrical plane of the cross section of their bases, located in the radial and / or tangential plane of the cross section to it disks passing through the axis of symmetry of each glass from the side of the hexagonal surface, and the gap between the glasses is selected from the condition of achieving the possibility of their free expansion at maximum operating temperature.

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