RU75007U1 - HEAT EXCHANGE PACKING OF REGENERATIVE AIR HEATER - Google Patents

Abstract

1. Heat exchange packing of a regenerative air heater, containing packs of cold and hot layers, each of which consists of a frame and alternating filling and spacer metal profiled sheets laid in it, and the profile of all filling sheets has the shape of a wave, the crests of which are located at an angle of 30 ° to the direction of the aerodynamic flow, and the profile of all spacer sheets, in addition to the same waves, has corrugations spaced apart from each other in the form of a wave of greater height, located parallel to the direction of the aerodynamic flow, characterized in that the parameters of the profile of the sheets of the hot layer are: wave height of the filling sheet: 3 , 5-3.8 mm; wave height of the spacer sheet: 3.1-3.8 mm; wave pitch of the filling and spacer sheets: 13-17 mm; distance between the corrugations of the spacer sheet: 29-81 mm; corrugation height of the spacer sheet: 8.0-14.0 mm; and the parameters of the cold layer sheet profile are: of the filling sheet: 3.0-3.3 mm; wave height of the spacer sheet: 2.8-3.4 mm; wave pitch of the filling and spacer sheets: 13-17 mm; distance between the corrugations of the spacer sheet: 29-81 mm; height spacer sheet corrugation: 11.0-14.0 mm 2. Heat exchange packing according to claim 1, characterized in that the frame contains side and end walls in the form of solid sheets. Heat exchange packing according to claim 1, characterized in that the filling and spacer sheets are laid in the frame in a substantially radial direction. 4 Heat exchange packing according to claim 1, characterized in that the height of the hot bed packing sheets does not exceed 700 mm.

Description

The utility model relates to heat transfer gaskets of regenerative rotary air heaters and can be used primarily in the power industry.

Known gasket regenerative air heater according to SU 1105734 containing covered by the casing of a package of metal plates with longitudinal distance corrugations. In this case, the plates are located in a tangential direction. The known packing has a small metal consumption due to the implementation of the plates and the casing of the same thickness, but has a low heat transfer efficiency, which is caused by the used profile of the plates.

Closest to the utility model is the heat exchange packing of the regenerative air heater of the Beloozersk Power and Mechanical Plant (http://www.bemz.biz), containing packets of cold and hot layers, each of which consists of a frame and alternating filling and spacing metal layers laid in it in the tangential direction sheets with the profile "KRAFTLAGEN" (http://www.paragonairheater.com/basketed_ elements.htm). The profile of all the filling sheets has a wave shape, the ridges of which along the height of the sheet are located at an angle of 30 ° to the direction of the aerodynamic flow, and the profile of all the spacing sheets, in addition to the same waves, has corrugations spaced apart from each other in the form of a wave of greater height parallel to the direction of the aerodynamic flow.

However, the parameters of the sheet profile used in the known packing do not allow to achieve the maximum heat transfer capacity of the packing.

The objective of the utility model is to increase the heat transfer capacity by selecting the optimal profile parameters for both filling and spacer packing sheets.

This problem is solved by the fact that in the heat exchange packing of a regenerative air heater containing packages of cold and hot layers, each of which consists of a frame and alternating filling and spacing metal profiled sheets laid in it, and the profile of all filling sheets has a waveform, the ridges of which are height leaf

are located at an angle of 30 ° to the direction of the aerodynamic flow, and the profile of all the spacing sheets, in addition to the same waves, has corrugations spaced from each other in the form of a wave of a higher height, parallel to the direction of the aerodynamic flow, according to the utility model, the profile parameters of the sheets of the hot layer are:

wave height of the filling sheet: 3.5-3.8 mm; spacing wave height: 3.1-3.8 mm; wave step of the filling and spacing sheets: 13-17 mm; distance between the corrugations of the spacer sheet: 29-81 mm; corrugation height of the spacer sheet: 8.0-14.0 mm;

and the profile parameters of the sheets of the cold layer are:

wave height of the filling sheet: 3.0-3.3 mm; spacing wave height: 2.8-3.4 mm; wave step of the filling and spacing sheets: 13-17 mm; distance between the corrugations of the spacer sheet: 29-81 mm; corrugation height of the spacer sheet: 11.0-14.0 mm.

Such profile parameters of the packing sheets make it possible to provide the optimum ratio between the aerodynamic drag of the packing and the heat transfer rate, which ultimately determines the possibility of achieving the maximum heat transfer capacity of the packing.

Advantageously, the heat exchange packing frame comprises side and end walls in the form of continuous sheets. The presence of continuous walls of the frame eliminates the shunting of air flows through the side and end surfaces of the packing bags and, in combination with the optimal overall dimensions of the bags in plan, allows efficient sealing of the remaining small gaps (shunts) between the walls of the bags and the cell walls of the rotor of regenerative rotating air heaters by installing overlays from metal strips.

Preferably, the filling and spacing sheets are arranged in the frame in a substantially radial direction, which improves the manufacturability of the packages and makes it easier to install them in the cells of the rotor sectors of the regenerative rotating air heaters in the presence of beam distortions on the hot side of the rotor due to the lower stiffness of the package in the tangential direction.

In addition, the height of the sheets of the packing of the hot layer mainly does not exceed 700 mm.

Figure 1 shows one of the packages of heat exchange packing in accordance with the present utility model, general perspective view;

figure 2 shows two adjacent sheets of packing in cross section;

figure 3 is the same, a view in plan with a partial pullout.

The heat exchange packing package shown in FIG. 1 contains a frame 1, the side and end walls of which are made in the form of solid sheets, respectively, 2 and 3. In the frame, alternating filling and spacing metal shaped sheets, respectively, 4 and 5 are arranged in a substantially radial direction The profile of all the filling sheets 4 has a waveform (figure 2), the ridges of which along the height of the sheet are located at an angle of 30 ° to the direction of the aerodynamic flow A (figure 3). The wave height (B) of the filling sheets of the hot layer is 3.5-3.8 mm, the wave pitch (t _in ) is 13-17 mm. For the cold layer, the wave height (5) of the filling sheets is 3.0-3.3 mm, the wave step (t _in ) is 13-17 mm.

The spacer sheets, in addition to the same waves, have corrugations 6 in the form of a wave of greater height (Fig. 2) located parallel to the direction of the aerodynamic flow A (Fig. 3). The corrugations 6 provide the necessary distance C between the sheets stacked in the package for the passage of the gas-air flow (figure 2). The spacer sheets of the hot layer have the following parameters: wave height (a) - 3.1-3.8 mm; wave pitch (t _in ) - 13-17 mm; the distance between the corrugations (t _g ) - 30-80 mm; corrugation height (h _g ) - 8.0-14.0 mm. For the cold layer, the wave height (a) of the spacer sheets is 2.8-3.4 mm; wave pitch (t _in ) - 13-17 mm; the distance between the corrugations (t _g ) - 30-80 mm; corrugation height (h _g ) - 11.0-14.0 mm.

Thus, both for filling a hot layer and for filling a cold layer, profiles of filling and spacing sheets of the same type are used, differing only in their geometric parameters.

The thickness of the sheets of the hot layer is 0.5-1.0 mm, and the cold layer is 0.5-1.6 mm.

Preferably, the height H (FIG. 3) of the sheets for the hot layer is not more than 700 mm.

The profiles of the filling and spacing sheets of the packing with the above parameters make it possible to intensify heat transfer and, as a result, obtain an increase in heat removal from a surface unit and increase the resistance of the packing surface to pollution, which is confirmed by the results of operation on

power plants. High heat transfer performance of the packing reduces the total heat exchange surface area of the packing. The smaller area of the heat-exchange surface allows to reduce its weight and to provide the calculated heat removal in regenerative rotating air heaters with a packing of a lower height and correspondingly lower aerodynamic resistance, which will reduce the dimensions of the rotor at the design stage.

Reducing the length of the channel (diluting the total height of the hot layer by several tiers, each of which does not exceed 700 mm in height) makes it possible to increase the heat transfer coefficient of the packing surface α _k due to the turbulization of gas and air flows in the gaps between the tiers of the packing of the hot layer and, thus, obtain additional stable heat removal in comparison with the design version of the hot layer packing packages.

Claims (3)

1. Heat exchange packing of a regenerative air heater, containing packages of cold and hot layers, each of which consists of a frame and alternating filling and spacing metal profiled sheets laid in it, the profile of all filling sheets having a waveform, the ridges of which are arranged at an angle of 30 along the height of the sheet ° to the direction of the aerodynamic flow, and the profile of all the spacing sheets, in addition to the same waves, has spaced corrugations in the form of a wave of greater height, located th parallel to the direction of aerodynamic flow, characterized in that the profile parameters sheets hot layer comprise: wave height of the filling sheet: 3.5-3.8 mm; wave height of the spacer sheet: 3.1-3.8 mm; wave step of the filling and spacing sheets: 13-17 mm; the distance between the corrugations of the spacer sheet: 29-81 mm; corrugation height of the spacer sheet: 8.0-14.0 mm; and the profile parameters of the sheets of the cold layer are: wave height of the filling sheet: 3.0-3.3 mm; wave height of the spacer sheet: 2.8-3.4 mm; wave step of the filling and spacing sheets: 13-17 mm; the distance between the corrugations of the spacer sheet: 29-81 mm; corrugation height of the spacer sheet: 11.0-14.0 mm. 2. Heat transfer packing according to claim 1, characterized in that the frame contains side and end walls in the form of continuous sheets. 3. The heat transfer packing according to claim 1, characterized in that the filling and spacing sheets are laid in the frame, essentially in the radial direction. 4, Heat transfer packing according to claim 1, characterized in that the height of the sheets of the hot layer packing does not exceed 700 mm.