SU1323130A2 - Connection drive device for tube mill - Google Patents

Abstract

The invention relates to drive coupling devices, mainly pipe mills, and can be used in the cement, mining and other industries. The aim of the invention is to reduce the backlash and dynamic loads in the axial direction. The device contains a compensating connecting shaft 1 with flanges 2 and 3, a flange coupling half 4 of the gearbox 5, a pipe mill pipe 6, tangential drafts 7 with spherical bearings 8 at the ends, cantilever axes 9 and central adjustable stops 10. Flanges 2 and 3 joints They are equipped with flanges of half coupling 4 and connecting pipe 6 by means of three CONSOL axes 9 fixed on each of the flanges and three tons of g 7. The adjustable stops 10 are located in the center between the connected shafts. Adjustable stops 10 include a screw 12, a nut 13, a spring-loaded stopper. A hole is made on the threaded end of the 18th screw. On the head 19 of the screw holes are made for unlocking and pivoting levers. 1 hp f-ly, 7 ill. C f (L oo y so oo go

Description

The invention relates to coupling drive devices, mainly pipe mills, and can be used in the cement, mining and other industries of the industry,

The purpose of the invention is to increase reliability by reducing backlash and dynamic loads in the axial direction.

Figure 1 shows the connecting drive unit tube mill, a longitudinal section; figure 2 - sections aa in figure 1; on fig.Z-node

I figure 1; Fig. 4 shows an adjustable stop in the locked state;

IIa fig.Z; on fig.Z - section BB in figure 4; Fig. 6 shows an adjustable stop in the state of separation, node II in Fig. 3; 7 - section bb

figure 6.

The connecting drive unit contains a compensating intermediate shaft 1 with end flanges 2 and 3, a flange coupling half 4 of a gear reducer 5, a discharge pipe 6, tangential rods 7 with spherical bearings 8 at the ends, cantilever axes 9 and central adjustable stops 10.

The flanges 2 and 3 of the intermediate shaft 1 are connected respectively to the flange of the coupling half 4 of the gearbox 5 and the flange

pipe 6 using three console

axes 9 mounted on each of the connected flanges, and three tangent ps and 7, spherical bearings 8 of which are fixed to the ends of the axes 9. Adjustable stops 10 are located in the center between the connected shafts and fixed on the ends of the intermediate shaft 1. Central stops 11 mounted on the ends of the coupling half 4 gearbox and pipe 6 stranded} 1itsy. The flanges 2 and 3 of the intermediate wool 1 and the flanges of the coupling half 4 of the nozzle 6 are made in the form of triangles, the tops of which are fixed

which are solo axes 9 of tangential tons of r 7, Q is a single knot, ready

The adjustable stops 10 comprise a screw 12, a nut 13, a stopper 14, a gland spring 15, a pin 16 and a screw-on head 17. The screw 12 has

The dp is installed into the nut 13. Before screwing the assembled screw 12 into the nut 13 into the hole 21 of the screw 12, a separating lever 23 is inserted, which

The thread 18 and the head 19. On its threaded bevel 31, the slipper on the cone end 18, the ninte 12 is made at less than 30, displaces the pin 16 in the axial direction, at least one transverse opening. Due to bevels 29 and 28, 20 for the stopper 14. At the head 19, the mixing of the stopper 14 in the

tl 12 n different planes are made

transverse bores 21 and 22, respectively, for spacing and pivoting adjustment levers 23 and 24.

The screw 12 has a through central hole 25 in which a threaded hole 26 for a threaded plug 17 is made on the side of the head 19. The nut 13 inside the threaded hole has at least one longitudinal groove 27 for mutually fixing the screw 12 and the nut 13 by the stopper 14. With increasing number notches 27 respectively in the same

the accuracy of the adjustment and the stopper is increased.

The stopper 14 has a cylindrical outer surface and a blind hole for the gland spring 15. In the middle part it has flats with bosses 28 that interact with a bevel 29 made at one end of the pin 16. At the other end of the pin 16 is a cone 30. The screw plug 17 is screwed the screw hole 26 of the screw 12. In this case, the end of the plug coincides with the generatrix of the transverse hole 21 and the cone 30 of the pin 16 rests against it when the screw 12 is locked.

The assembly of the screw 12 with the locking device prior to its installation at the place of operation is carried out as follows.

In the transverse hole 20 of the screw 12, a stopper 14 is installed with the gland spring 15 and held in the recessed state until

until in the central hole 25 from the side of the head 19 of the screw 12 the pin 16 will not be installed and the threaded plug 17 is screwed, which with its end prevents the pin 16 from falling out

screw 12. In this case, the end of the plug 17 is set to coincide with the generatrix of the transverse holes 21. Thus, the screw 12 assembled with the adjusting abutment parts is installed in the nut 13. Before screwing the assembled screw 12 into the nut 13, the hole 21 of the screw 12 is inserted unlocking lever 23, which

the body of the screw 12 and the compression of the spring 15.

3P

The stopper 14, the wrinkle below the internal diameter of the thread on the screw 12, does not interfere with the screwing of the screw 12 into the nut 1 3.

After the screw 12 is screwed into the nut 13, the lever 23 is removed from the hole 21, the stopper 14 under the action of the spring 15 automatically enters the longitudinal groove 27 of the nut 13 and thereby locks the screw 12 relative to the nut 13. At the same time, the stopper 14 with its bevel 28 acts on the bevel 29 pin 16 and shifts the latter until it stops at the end of the plug 17.

If at the moment when the lever 23 is retracted from hole 31 after adjusting the screw and the stopper 14 does not coincide with the groove 27 of the nut 13 and rests against the inner surface of the thread of the nut 13, then, first of all, by turning the screw 12 lever inserted into the transverse hole 22, under the action of the spring 15, the stopper 14 enters the groove 27 secondly, during operation of the device when turning the screw 12, the stopper 14 under the influence of the spring 15 falls into the nearest groove 27 of the nut 13 and thereby automatically locks the screw 12 regarding the nut 13. This eliminates arbitrary deregulation screw connection and ensures reliable locking of the adjustable stops 10.

The clearance (clearance) E between the end face of the head 19 of the screw 12 and the stop 11 is adjusted as follows.

The screw connection of screw 12 - nut 13 is ensured by inserting lever 23 into the cross hole 21 of the screw when the stopper 14 comes out of the longitudinal groove 27 of the nut 13. Rotating screw 12 in the nut 13 with lever 23 or 24 adjusts the clearance E, removing lever 23 from the holes 21 of the screw 12 spring-loaded stop 14 is released and is inserted into the longitudinal groove 27 of the nut 13, and the screw joint is locked. If the stopper 14 does not turn out against the groove 27, then using a lever installed in the hole 22, you can turn the screw 12 to the nearest longitudinal groove 27, a hundred pores 14, which automatically drops into the groove 27. It is possible and does not bring the stopper 14 under the grooves 27, as when operating, in the case of turning the win304

That 12 is relative to the nut 13, the stopper 12 itself automatically enters the groove 27 and stops the screw connection from further turning.

The clearances (backlash) E are minimal (for example, 1-3 mm) taking into account the compensation of temperature deformations (stretch-compression) and uniform on both sides relative to the nominal axial position of the intermediate shaft 1. This reduces the tangential t 7 of 7 when the reversible to the load, when the pulls 7 operate in compression, and accordingly reduces the axial component of the circumferential force during the transmission of torque. With a decrease in the axial load and its dynamism on the intermediate shaft 1, the axial forces acting on the bearings of the connected shafts of the gear reducer and the mill decrease accordingly, which increases their reliability and durability. The coupling drive unit of the tube mill operates as follows.

Due to the installation errors of the gear reducer and the mill on the foundation, as well as operating force and temperature deviations, wear of the mill bearings, shrinkage of the foundations and residual deformations of parts, the connected shafts of the reducer and the mill will be misaligned and non-parallel. These errors of the mutual arrangement of the shafts of the gearbox and the mill during their rotation are compensated for by the floating intermediate shaft 1, which is radially mounted on the three tangles of the self-aligning thrust bars 7 through the spherical bearings 8 and in the axial direction is limited by central adjustable stops 10. I

During the working rotation of the mill, the tangential rods 7 work to stretch and the intermediate shaft 1 axially self-aligning along them, being with a gap between the central stops 11 or pressing their adjustable stop 10 to one of the central stops 1 1.

After turning off the electric motor, the mill begins to balance (swing) in different directions under the action of an unbalanced mass of the material being ground and grinding media. Mills513

The center and drive alternately become the leading and the driven. In this case, the direction of the torque moment changes accordingly, and the tangential pulls 7 operate either in tension or in compression.

From the effect of circumferential force on compressive tangential 7, due to their skew, there are component forces directed along the intermediate shaft, which, choosing an axial clearance E, displace the intermediate shaft 1 in the direction opposite to the inclination of the tangential 7

Since the gaps E are adjusted by a very small amount (1-3 mm), the transverse tangential tg and axial component forces decrease accordingly, and the dynamic loads decrease, and this increases the reliability and durability of the spherical bearings 8 of the connecting device and axial bearings of a reducer and mill.

The advantages of the proposed connecting drive unit of a pipe mill are to increase the reliability and durability of the connecting device, gearbox bearings and the mill, to speed up installation and repair work in hard-to-reach places (between the flanges to be connected). At the same time,

idle mills are running and the use of calendar time and the average annual productivity of the mill and the mill aggregate as a whole increase accordingly.

Claims (2)

1. Connecting drive unit tube mill for auth.St. No. 737006, characterized in that, in order to increase reliability by reducing backlash and axial dynamic loads, the compensating connecting shaft is provided with adjustable stops coaxially fixed at its ends, and the output shaft of the reducer and discharge nozzle of the trunnion are fitted with fixed ends at their ends central limit stops mi. 2. A device according to claim 1, characterized in that each adjustable stop is made in the form of a screw connected to the shaft end by means of a threaded plug with a spring-loaded screw stopper, and the screw head is made with diametrically arranged openings for the lever of rotation of the screw. ) cpufZ Fig.z / 74 / J FIG. five /four 12 TS Editor I.Klsarda Compiled by V.Gubarev Tehred A. Kravchuk Proofreader V. But ha 2893/7 Circulation 572Subscribe VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab, d. A / 5 Manufacturing and printing company, Uzhgorod, Project St., / 4 Fig 7