CS232412B1 - Loading of tube furnace systems - Google Patents

Abstract

The invention relates to the suspension of tube systems of reaction or heating furnaces using ropes, pulleys, weights, rods and levers. Suspension using ropes alternately guided by pulleys of the suspensions to the structure and by pulleys of the suspensions of the tubes, where the ropes are anchored to the supporting structure with one end and to the opposite weights with the other end, the essence of which lies in the fact that the anchoring points (8) of the two ropes (2) are mirror-imaged side-by-side in relation to the weights (0). The pulleys (3) of the suspensions are connected to the supporting structure or tubes (6) firmly by means of horizontal pins. optionally by means of upper swing rods (4) and lower swing rods (5) pulled or pushed, which are provided with a scale (7) with a plumb line (12). The suspension according to the invention can be applied to all thermal devices where the pipe section is placed in a vertical position, especially for furnace systems in the petrochemical industry.

Description

The invention relates to the suspension of pipe systems of reaction or heating furnaces by means of ropes, pulleys, weights and levers.

Known pyrolysis, reforming and other types of reaction or heating furnaces with vertical tube configuration have to address the question of the effect of self weight and considerable thermal expansion of the tube system on its strength and operational reliability. The conditions under which this problem is solved are extremely time-consuming because the pipe systems operate at very high temperatures, sometimes with higher internal working pressure values and despite being used in high-value highly refractory materials under very low permissible stress conditions.

in addition, the durability and reliability of these systems is limited by the inadmissibility of major permanent deformations, since the highly refractory materials used to produce them, for example by centrifugal casting, become significantly brittle under operating conditions. The situation is often complicated by the corrosive action of the working substances, which work in the same direction and the final working conditions are therefore even more difficult.

The actual mission of the suspension of pipe systems is therefore to create conditions for the suppression of these adverse influences as much as possible, ie it is only possible to realize as much as possible free thermal and pressure dilatation. Limiting this dilatation or imposing a system of further displacements reduces the service life of the system. From the point of view of fulfilling such a formulated function, the most difficult situation is when the tube temperatures are not the same and the difficulty increases as the temperature difference increases. If the temperatures of all pipes are to be technologically equal, individual differences occur, for example due to different heat input or heat dissipation, catalyst activity changes, etc.

The pipe system of the described furnaces usually consists of regularly arranged rows of pipes. For the purpose of this description, one row of pipes is called a section. Sections are most often planar formations.

It is known to suspend the furnace pipe system in which the axial resultant of the internal pressure in the pipes is used to absorb the gravity force. The system consists of vertical reaction tubes connected by a horizontal lower common collector supported on the supports. The tubes themselves can expand freely. It is assumed that the internal overpressure will compensate for their gravity force. However, due to manufacturing and operating inaccuracies, bending moments are created in the pipes, which cannot be compensated by the internal overpressure. The result is a special plastic instability, where the deflections of the tubes gradually increase, their changes in radiation, which in addition adversely affects further changes in their shape. The final stage is the exhaustion of limit deformation in creep and operational fracture.

In another known system, the individual tubes of the system are suspended on springs. The force in the springs is adjusted close to the weight of the respective tube, so that the influence of the dead weight is compensated. However, this system has to be complicated to set up, its design is very complex, because at the final spring stiffness it must allow for dilatation movements which in turn lead to grain forces in the springs. Therefore, this solution is only approaching the set target and the difference has to be paid again by reducing the lifetime of the system. This deficiency can be influenced to some extent by the use of special, relatively complex hinges of constant force. However, their operation is limited, complicated and expensive, and the presence of friction negates their benefits to some extent. It is virtually never possible to adjust them to the actual gravity forces at the suspension points due to the production weight tolerances of the system.

Rather, this problem is solved by known furnaces in which individual counterweights are used. Each pipe - or pair - of the system is equipped with a drawbar system with a counterweight, so that the compensation of the gravity forces is very good and it is possible to carry out individual balancing of pipes and weights and compensate for manufacturing deviations. Weight of the linkage suspension system

- the counterweight increases the load-bearing steel. construction, which again increases its weight. There are also considerable problems with the overall furnace layout, as the lever system and weights are very space-intensive. The necessary compromise in the overall suspension of the furnace dimensions leads to its price increase and even, due to increased heat losses, also to the deterioration of economic operating indicators.

Another known embodiment suspends each row of the pipe system by means of pulleys, one rope and one weight. One end of the rope is anchored to the support structure and is alternately guided from pulleys fixed to the support structure to pulleys fixed to the tubes. The other end of the rope is tensioned by a weight. This design almost does not burden the load-bearing structure, but also enables individual weight balancing of the series, but it has - particularly in the case of a plurality of pulleys - a significant disadvantage, namely the unevenness of the forces in the individual hinges caused by friction losses. The decrease in force in the ropes can be very significant, leading to additional stresses and to a significant hysteresis behavior of the system.

A drawback of the rope suspension mentioned in the previous paragraph substantially eliminates the embodiment which suspends the tubular or hairpin sections by means of a single rope, alternately guided from pulleys anchored to the supporting structure to pulleys fixed to the tubes of the tubular section. freely moving. Due to the two-sided application of the weight forces of the weight, the unevenness of the suspension forces is considerably less than in other known embodiments. However, to avoid accidental overweighting, this embodiment requires a special restrictor device. Since only one cable is used, there is a certain danger to the operation in the event of its failure, which also applies to other known rope suspensions described above.

The described drawbacks are remedied to a large extent or entirely by hanging the pipe systems of the furnaces according to the invention by means of ropes alternately guided by the hinged pulleys to the structure and the hinged pulleys, where the ropes are firmly anchored to the supporting structure that the anchoring points of the two ropes are alternately mirrored in relation to the weights. The hinge rollers are connected to the supporting structure or to the pipes firmly by means of horizontal pins, possibly by means of upper swivel rods and lower swivel rods drawn or pushed, which are provided with a plumb line.

Due to the application of the weight of the weight alternately on two loops alternating laterally, the unevenness of the suspension forces is substantially smaller than in other known embodiments. This effect of the invention has a direct positive effect on the service life of the system.

In case of uneven distribution of pipe temperatures, especially in the case of dangerous overheating, some of them can cause thermal expansion without substantial change of the hinge forces.

Another effect is that weights do not need to be equipped with a restraint against accidental transport and further increase operational reliability. The system thus designed has great operational certainty, since even a failure of one of the ropes itself is very unlikely to jeopardize the operability of the suspension for a longer period of time, so that the failure can be remedied without stopping the furnace.

Thus, the rope suspension according to the invention exerts almost virtually the same and constant force on any, preselectable track with a very easily adjustable value of this force by varying the weight of the weight at each hinge point compared to special constant-force spring hinges. as standard and mass-produced parts can be used, for example, used in railway electrification. Furthermore, it is operationally reliable because it has a very small number of simple and identical parts. They can have their own weights. the well-known construction of cheap circular cylinders, made, for example, of concrete such that they are provided with an opening, a sliding groove and a protrusion, so that they can be slid freely onto the support rod without having to handle the remainder of the weights or disassembly.

They can be made of a number of sizes, which can be composed of any required final weight, possibly carry out reweighing.

According to the invention, two ropes, each alternating with pulleys with common horizontal axes forming their own suspension on the structure and on the tube or hairpin, are used for hanging each section of tubes or hairpins. The ropes have one anchor point on the load-bearing structure and the other end are pulled by the weight of the weight. The anchor points are alternately offset from one another. The hinges themselves consist of two pulleys with a common horizontal axis, with the exception of external hinges, around which the respective ropes coil. The axis of the pulleys is formed by a pivot, the pivot is connected to a pivot rod, the other end of which is again fixed by means of a pivot either to the supporting structure or to the pipe itself. However, this rod can also be omitted. The minimum number of rollers required is four times the number of tubes. The total number of pulleys may generally be greater than said minimum possible number.

According to the invention, the ropes generally form a certain alpha angle within the suspension field between the hanging tubes with a vertical within the range of 0 ° to alpha S. 45 ° and is a function of the horizontal and vertical distance of the axes of adjacent pulleys in the suspension field, rope radius and nominal temperature expansion pipe at the joint of the pipe hinge.

According to the invention, a certain angle e can be selected by combining the horizontal and vertical spacing of the adjacent pulleys in the suspension field, the radius of the rope pulleys and the nominal temperature expansion of the pipe at the hinge joint. overheating of a single pipe. This value is both alpha and 25 °, but even a larger value may be acceptable, especially when a non-linear hinge is required.

The accompanying drawings show examples of suspension of tube or hairpin sections according to the invention, wherein Fig. 1 shows a situation where a hairpin section is provided with one pivoting, sliding and fixed point and one hairpin is suspended on one hinge. Giant. 2 and 3 illustrate the suspension of multiple tubes or hairpins on a single hinge.

FIG. 1 shows a suspension formed by two ropes <2, each of which has an opposing anchor 8, and two weights 4 fixed to the ends of the ropes. The ropes are guided by pulleys 6, alternately on the hinge side, to the structure and to the tubes 6. Between the pulleys 6 and the furnace structure there are upper pivot rods 6 which are pulled or pushed. Similarly, the rollers 6 of the pipe hangers are connected to the tubes themselves by pivot rods. However, the rods 6 and 6 may be partially or completely omitted. By properly selecting the lengths of the suspension rods 5 and 6, a further uniformity of the forces in the system can be obtained, since the shear deviates from the average values of the forces by a certain angle due to friction. This angle can be controlled by means of a suitable scale 6 and a plumb line 12. If necessary, the upper pivoting rods 8 can be returned to their initial position by applying a small horizontal force. Furthermore, the function of the rods according to the invention is also important for compensating the horizontal dilatations of the system, so that the alpha angle is maintained along the entire length due to both friction and dilatations to a very low tolerance.

The individual lower pivoting rods 6 are provided with horizontal weight levers 60, 70 for suspending a plurality of tubes or hairpins 6 on a single hinge.

The total resultant of all suspension forces acting on the suspended tubular section may be less, equal, or greater than its gravity force. Since the tubular section must additionally be connected to the inlet or outlet of the working medium, and a perfect balancing of the gravity forces is impossible in practice, even though weights according to the invention are most accurately feasible, the tubular section can have at least one fixed, rotatable, a stop point located at any predetermined location. In FIG. 1, the tube section 6 has a rotating and sliding 10 and a fixed 11 point.

The proposed suspension of the tube or hairpin sections according to the invention can be used in all heating devices where the section is placed in a vertical position, especially for furnace systems of the petrochemical industry.

Claims (3)

SUBJECT OF THE INVENTION Suspension of furnace pipe systems by means of ropes, alternately guided by the hinge rollers to the structure and the hinge rollers, where the ropes are firmly anchored to the load-bearing structure and the other end to opposite weights, characterized in that ) are alternately mirror-side in relation to weights (1). Suspension of the furnace pipe systems according to claim 1, characterized in that the pulleys (3) are fixedly connected to the supporting structure or pipes (6) by means of horizontal pins, possibly by means of upper pivot rods (4) and lower pivot rods (5). optionally pressed, provided with a scale (7) with a plumb line (12). Suspension of the furnace pipe systems according to claim 1, characterized in that horizontal weight levers (13, 14, 15) for attaching the pipes (6) are attached to the hinge.