RU224963U1 - Cooling Tower Axial Fan Wheel - Google Patents

Abstract

The utility model relates to the field of fan engineering, in particular to the design of wheels for axial fans of cooling towers. The wheel of an axial fan of a cooling tower contains a hub with a support disk fixed to it and working blades, the butts of which are clamped in grooved, arched in cross-section recesses of the bases and are evenly located around the circumference on the support disk, while the hub is made with upper and lower rings, the support disk is fixed to its lower ring by means of a bolted connection, on the supporting disk there is a second row of bases similar to those described above, evenly around the circumference, and the number of bases of the second row is equal to the number of bases of the first row and the number of working blades, and the recesses of the bases of the second row are located coaxially with the recesses of the bases of the first row, on the upper ring the hubs are fixed radially and perpendicular to the hub axis; metal linings are in the form of flat rectangular plates with a narrowed end section connected by a bolted connection to the upper ring of the hub, and the number of rectangular plates is equal to the number of blades, and they are evenly spaced around the hub parallel to the support disk, and clamping strips, structurally similar to the above-described bases, are pressed against the rectangular plates opposite the above-described bases for the butt of the blades, forming two rows of clamping strips located circumferentially around the hub, and grooved recesses made in the clamping strips with oppositely located recesses of the bases of the first and second rows of bases form radial passages, into each of which the butt of the working blade is inserted, and the butt of the blade located in the recesses of the bases and clamping strips is simultaneously clamped between the bases of the first and second rows and the clamping plates of the first and second rows located opposite them by means of bolted connections made with bolts passed through through holes made in rectangular plates, clamping strips, bases located opposite them and the support disk. As a result, it is possible to increase the reliability of fastening the butt of the fan blades to the hub. 5 ill.

Description

The utility model relates to the field of fan engineering, in particular to the design of wheels for axial fans of cooling towers, and can be used to create new cooling towers with axial fans for the oil and gas, petrochemical and chemical industries, as well as for regional energy enterprises and other industries.

An axial fan impeller is known, containing a hub in the form of a disk with a central bushing and blades fixed in the hub by their cylindrical shanks with shoulders, while one of the surfaces of the disk is made with cradle having a cylindrical surface, and above each cradle there is an insert with a mating cylindrical surface. , forming with the cradle a space for placing the blade shanks with the possibility of rotation (see RF patent for invention No. 2205299, class F04D 29/32, published 05/27/2003).

However, this design of an axial fan wheel has a relatively complex structure, which leads to an increase in the complexity of its manufacture and an increase in the complexity of its maintenance during its maintenance.

The closest to a utility model in terms of technical essence and the achieved result is a wheel of an axial fan of a cooling tower, containing a hub with a support disk fixed to it, working blades, the butts of which are clamped in grooved recesses of the bases, evenly distributed around the circumference on the support disk (see utility patent RF model No. 196830, class F04D 29/32, published 03/17/2020).

However, the use of a base for fixing the butts of the blades in the form of a single part with fixation of the butts by means of linings in the form of two relatively narrow bandages leads, on the one hand, to an increase in the material consumption of the bases, and on the other hand, to an increase in contact loads in the place of fixation of the butts with relatively narrow linings, which reduces reliability of fixation of the butt of the blade on the base.

The technical problem to be solved by this utility model is to overcome the identified shortcomings in known technical solutions.

The technical result is that it is possible to increase the reliability of fastening the butt of the fan blades to the hub.

The specified technical problem is solved, and the technical result is achieved due to the fact that the wheel of the axial fan of the cooling tower contains a hub with a support disk mounted on it and working blades, the butts of which are clamped in grooved, arched in cross-section recesses of the bases and are evenly located around the circumference on the support disk, wherein the hub is made with upper and lower rings, the support disk is fixed to its lower ring by means of a bolted connection, a second row of bases similar to those described above is located on the support disk evenly around the circumference, and the number of bases of the second row is equal to the number of bases of the first row and the number of working blades, and the recesses of the bases of the second row are located coaxially with the recesses of the bases of the first row; on the upper ring of the hub, metal linings in the form of flat rectangular plates with a narrowed end section, connected by means of a bolted connection to the upper ring of the hub, are fixed radially and perpendicular to the hub axis, and the number of rectangular plates is equal to the number of blades and they are evenly located around the circumference around the hub parallel to the support disk, and clamping strips are pressed against the rectangular plates opposite the above-described bases for the butt of the blades, structurally similar to the above-described bases to form two rows of clamping strips located circumferentially around the hub, and grooved recesses made in the clamping strips with opposite the recesses of the bases of the first and second rows of bases located by them form radial passages, into each of which the butt of the working blade is inserted, and the butt of the blade located in the recesses of the bases and clamping bars is simultaneously clamped between the bases of the first and second rows and the clamping plates of the first and second rows located opposite them by means of bolted connections made with bolts passed through through holes made in rectangular plates, clamping strips, opposite bases and a support disk.

In the course of the study, it was revealed that it is possible to increase the reliability of fastening the butts of the blades due to the fact that the bases and clamping strips are located around the circumference in two rows, and the butts of the blades are clamped in grooved recesses both from above and from below, which, in comparison with the closest analogue, allows you to increase the contact area between the butts and the surface of the grooved recesses. As a result, the contact area increases with a corresponding increase in the reliability of fastening the butt of the blade, and at the same time it is possible to provide a distributed load at the point of contact of the butt surface and the grooved recesses, which also makes it possible to increase the reliability of fastening the butt of the blade, and consequently the entire blade.

In fig. Figure 1 shows an axonometric image of a cooling tower axial fan wheel.

In fig. Figure 2 shows an axonometric image of the wheel hub of the axial fan of the cooling tower.

In fig. Figure 3 shows a top view of the wheel blade of the axial fan of the cooling tower.

In fig. Figure 4 shows a top view of the wheel hub of the axial fan of the cooling tower.

In fig. 5 shows section A-A in FIG. 4.

The wheel of the axial fan of the cooling tower contains a hub 1 with a support disk 2 fixed on it and working blades 3, the butts 4 of which are clamped in the grooved, arched in cross-section recesses 5 of the base 6 and are evenly located around the circumference on the support disk 2.

Hub 1 is made with upper 7 and lower 8 rings. The support disk 2 is fixed to the lower ring 8 of the hub 1 by means of a bolted connection 9.

On the support disk 2, a second row of bases 10 similar to those described above is located evenly around the circumference, and the number of bases 10 of the second row is equal to the number of bases 6 of the first row and the number of working blades 3.

The recesses 11 of the bases 10 of the second row are located coaxially with the recesses 5 of the bases 6 of the first row.

On the upper ring 7 of the hub 1, metal linings in the form of flat rectangular plates 12 with a narrowed end section connected by a bolted connection 13 to the upper ring 7 of the hub 1 are fixed radially and perpendicular to the axis of the hub 1.

The number of rectangular plates 12 is equal to the number of blades 3, and they are evenly spaced around the hub 1 parallel to the support disk 2.

Clamping strips 14, structurally similar to the above-described bases 6 and 10, are pressed to the rectangular plates 12 opposite the above-described bases 6 and 10 for the butt 4 of the blades 3, forming two rows located circumferentially around the hub 1 of the clamping strips 14, and the clamping strips 14 made in the clamping strips 14 are grooved recesses 15 with opposite recesses 5 and 11 of the bases of the first 6 and second 10 rows of bases form radial passages, into each of which the butt 4 of the working blade 3 is inserted.

Located in the recesses 5, 11 and 15 of the bases 6 and 10 and the clamping strips 14, the butt 4 of the blades 3 is simultaneously clamped between the bases 6 and 10, respectively, of the first and second rows and oppositely located clamping strips 14 of the first and second rows by means of bolted connections 16, made with bolts 17 passed through through holes made in rectangular plates 12, clamping strips 14, oppositely located bases 6 or 10 and support disk 2.

The axial fan wheel (Fig. 1) of the cooling tower operates as follows.

The wheel is installed in the cooling tower fan at the working end of the drive output shaft (not shown in the drawing) of the cooling tower fan.

Installation and rotation of the blades 3 with subsequent fixation at a given angle is carried out by placing the butts 4 of the blades 3 into the passages formed by the bases 6 and 10, as well as the clamping bars 14 and then the butts 4 are clamped between the above bases 6 and 10 and the clamping bars 4 with using bolted connections 16.

Next, the axial fan wheel is rotated from the above drive. When the blades 3 (Fig. 1) rotate, they create an air flow in the cooling tower.

If it is necessary to change the fan performance, stop the operation of the fan, loosen the clamp on the butts 4 of the blades 3 and rotate the blades 3 to set them at the required angle, after which the butts 4 are clamped as described above using a bolted connection.

The above-described design made it possible to create a cooling tower axial fan wheel, which has a simple and reliable design, which has low labor intensity in manufacturing and installing the wheel, as well as maintenance and replacement of blades during wheel assembly and repair.

Thus, the described design of the cooling tower axial fan wheel makes it possible to realize the stated technical result, namely, it is possible to increase the reliability of fastening the butts of the fan blades to the hub and, as a result, achieve increased reliability of the cooling tower axial fan wheel.

Claims (1)

A wheel of an axial fan of a cooling tower, containing a hub with a support disk fixed to it, working blades, the butts of which are clamped in grooved recesses of the bases, evenly located around the circumference on the support disk, characterized in that the hub is made with upper and lower rings, the support disk is fixed to it the lower ring by means of a bolted connection, while on the supporting disk there is a second row of bases similar to those described above evenly around the circumference, and the number of bases of the second row is equal to the number of bases of the first row and the number of working blades, and the recesses of the bases of the second row are located coaxially with the recesses of the bases of the first row, on the top the hub ring is fixed radially and perpendicular to the hub axis by metal linings in the form of flat rectangular plates with a narrowed end section connected by a bolted connection to the upper ring of the hub, and the number of rectangular plates is equal to the number of blades, and they are evenly spaced around the hub parallel to the support disk, and clamping strips, structurally similar to the above-described bases, are pressed against the rectangular plates opposite the above-described bases for the butt of the blades, forming two rows of clamping strips located circumferentially around the hub, and grooved recesses made in the clamping strips with oppositely located recesses of the bases of the first and second rows of bases form radial passages, into each of which the butt of the working blade is inserted, and the butt of the blade, located in the recesses of the bases and clamping bars, is simultaneously clamped between the bases of the first and second rows and the clamping bars of the first and second rows located opposite them by means of bolted connections made with bolts passed through through holes made in rectangular plates, clamping bars, oppositely located bases and a support disk.