DE27939C - Innovations to shut-off devices using regulators and steam engines - Google Patents

Description

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PATENT OFFICE.

PATENT LETTERING

CLASS 14: Steam Engines.

Patented in the German Empire on July 18, 1883.

The innovations consist in the combination of an ordinary double slide control, at which the regulator is not on. the shaft of the machine sits with a dynamometric Regulator, which is arranged on the drive shaft of the machine and which influences resistances is exerted by the load acting on the drive wheel of the machine.

The regulators not sitting on the shaft can be centrifugal regulators of any Forms, or they can be direct by the steam pressure from the boiler or the steam supply pipe be actuated.

However, the latter type of regulator is preferred for the following reasons. When regulating a steam engine, the resistance to be overcome by the engine, on the one hand, and the steam pressure, on the other, come into consideration. In most cases these two forces are continuously variable, and in order to give the machine the most uniform possible movement it is considered necessary that the regulator of the machine should be under the action of these two forces at the same time. W hen a machine ^T is regulated only by a Centrifugalregulator, wherein either of those regulator mounted on the shaft of the machine or at some other location, these two aforementioned forces acting on the valve control means of the speed change; consequently their action is indirect and not direct.

In order to obtain a direct regulation, which is influenced by both of these forces, should therefore preferably use a steam pressure regulator that does not sit on the shaft of the machine Connection with a dynamometric regulator, which is on the drive shaft of the machine is arranged to be applied.

Fig. Ι is a side view of the drive pulley and shows the connection of a dynamometric Regulator with a steam pressure regulator;

Figure 2 is a front view of the parts shown in Figure 1 with the vapor pressure regulator is replaced by a centrifugal regulator;

Fig. 3 is a perspective view of the parts shown in Fig.

Fig. 4 shows a basic outline of the same parts, as well as a part of the control which is on the opposite Side of the machine frame is arranged, the latter drawn broken off is,

Fig. 5 is a side view of the latter part of the control.

Figures 6, 7, 8, 9, 10, 15, 16, 17, 18 and 19 are Details of FIGS. 1 to 5.

Fig. 11 shows another in side view Construction of the dynamometric regulator and another type of control,

12 shows the device for a Corlifs control.

Figures 13 and 14 illustrate the application a cummer control.

Fig. 20 is a horizontal section through the steam cylinder showing the construction of the Slider;

Fig. 2i is a rear view of the expansion valve,

22 is a rear view of the basic slide valve; Figure 23 is an end view of the same.

A is the shaft of the machine. The drive pulley B sits loosely on the same. C is an arm which is attached to said shaft.

The two parts B and C 'are movably connected to each other by the rods D and the springs Z) ¹ £>, wherein said rods are fixed to the arm C, by reinforcements b at two of the spokes of the drive wheel to pass and means adjustirbarer nuts and washers d are held by springs D 'Z)' sandwiched between the washers and reinforcements. The arrows drawn in full lines, Fig. 1, show the direction of rotation of the shaft and the dotted arrows the direction of the resistance offered by the work which the machine has to cope with, in other words, the direction of the tension of the drive belt. As soon as the load increases, the springs Z) ¹ J? ¹ pressed together and wheel and arms C rotated against each other. This movement is transmitted to the sliding ring E by the angle lever FF ¹ F *. Each angle lever consists of the spindle F and the two angles F ¹ F "*. The spindles F are mounted at one end in the lugs C ¹ C ^{1 of} the hubs and held near the ends of the arms C by the tabs c .

The angles F ¹ are connected to the drive pulley by pins, which are inserted into sliding pins f , which in turn are mounted in the lugs b ¹ on the inner surface of the wheel tire. The angles F ² are connected by pegs to the links E ¹ , which in turn are hung with pegs on the tabs e (cf. FIGS. 18 and 19). These tabs protrude from the toroidal core e ² and are embedded in depressions in the side of the hub of the transverse arm C. As a result of this recess, the ring E is therefore moved in one direction or the other on the shaft when the stress on the machine changes. The movement of the ring on the shaft can be just as greater or even greater than the relative movement on the circumference of the drive pulley. If the arms F ^{2 are} chosen to be longer than the arm F ¹ , the movement of the ring on the shaft will be greater than the movement on the periphery of the wheel.

The effect of this dynamometric regulator is made possible by suitable gears Transferring the sliding ring to the control. Several arrangements are shown in the drawings shown for this, but they all work according to the same system.

The devices consist essentially of a shaft, a lever with variable Pivot point and a coulisse. This is also the case when the dynamometric regulator acts by means of a sliding eccentric, as shown in FIG.

Usually both regulators are connected to the coulisse, but you can also only associate one or the other with it. The purpose of the sliding lever is to allow each of the regulators to act independently of the other at any time Control can work.

In Figs. 13 and 14, the two operate Regulators against each other. In Figures 1 to 4 and 12 the construction is substantial the same with respect to the control, whereas Figs. 6-10, 11 and 15-17 Show modifications of the control.

The construction of the devices shown in FIGS. 1 to 4 and 12 is as follows: A slider E ² , provided with a protruding pin e \ FIGS. 18 and 19, is fitted in a slot in the bracket of the sliding ring. The rod of the other regulator J ¹ respectively. J " ¹ is connected to this pin e '. The coulisse G ^s is also attached to this pin e ', the sliding block of which is attached to the oscillating spindle G, which is held in a horizontal position by a strut G ¹ , and at the other end is provided with the arm G ^i. Coulisse G ³ moves in the head G ¹ of the spindle G. the strut G ¹ is of such a length that the spindle G DAF always on one side of the ring e is maintained, regardless of what position The coulisse G ³ is therefore always at an angle to the slot in the ring, Fig. 2. The coulisse can therefore not move without causing the spindle G to rotate.

The position of the slider E ² and that of the coulisse G ³ are changed by the action of the regulators / ' or _ / ² . In the arrangement shown in Fig. 2, any change in the position of the regulator balls will cause a change in the position of the slider E ″ and a lengthening or shortening of the coulisse arm G ³ . Such a change causes a rotation of the shaft G as a result of the inclined position which the coulisse G ³ assumes in relation to the slot in the sliding ring. The result remains the same even if the Regulatory ^{3 is} used as soon as the vapor pressure changes. It is thus seen, that a change in the speed (or the steam pressure, when the regulator J is needed ³⁾ causes a rotation of the shaft G, and that a change in the load, a displacement of the ring E, and thereby also a rotation of the shaft G \ caused. From the above it follows that everyone

■ the regulators can change the position of the shaft G without exerting any noticeable effect on the other regulator. The movements of the shaft G are transmitted to the controller through the arm G ¹ , the connecting rod g, the arm H \ the shaft H, etc.

In the construction shown in FIG. 12, the movement is transmitted to the control by means of the armature lever H ¹ and the rods H ^ H ^s. The connecting parts can be modified in various ways, depending on the construction of the machine on which they are to be mounted.

In Figs. 15 and 16, the shaft G is some distance from the ring E, and therefore a lever E * is engaged. The movement is transmitted to the coulisse G ^{3 by} means of the rod E ⁵ , which is connected to the sliding piece of the same.

The other regulatory is connected to the rod E ^b . The movement of the ring E will therefore cause a smaller or larger movement of the shaft G , depending on whether the other regulator has raised or lowered the sliding block of the coulisse.

In the construction shown in Fig. 11, the same effect is achieved in a somewhat different way. The coulisse is here denoted by JV '. The end point of the eccentric rod J is shifted by a regulator in the coulisse. Furthermore, the oscillations of the Coulisse JV ^{1 are} also varied by moving the eccentric using the dynamometric regulator on the shaft.

Another connection of the dynamometric regulator with a centrifugal regulator which is not seated on the drive shaft is shown in FIGS. Here the dynamometric regulator acts on the slide ring E; the lever E ¹ holds the rod E ^{e of} the counterweight and this is intended to increase or decrease the load caused by the counterweight W, depending on the required stress.

In this case the two regulators do not work independently by adding the resistor counteracts the centrifugal force on the regulator.

In Fig. 17 a device replacing the coulisse is shown. The arm G ³ is connected to the rod E ^b and itself cannot be changed in length. The lever arm is changed by two eccentrics 1 and 2. The eccentric 1 is attached to the shaft G and arranged in the other eccentric 2, which is connected to the regulator by the rod _ / '. Here again each regulator works independently of the other.

The construction of the pressure regulator shown in Figs. 1 and 3 and the connection of the same to the controller is as follows. J ³ is the regulator cylinder, _ / ₂ the piston rod, which is connected to the slide E ³ in the ring E sitting on the shaft or to another part of the regulating device, as can be seen from the various constructions shown. The piston is loaded by a set around the piston rod _ / ² spring, which can be adjustirt by a nut. The piston rod is rotatably connected to the piston, which is necessary because it is connected to a transversely displaceable part of the control. The steam in the boiler or in the main steam pipe acts on this pressure device through a small branch pipe. The pressure cylinder and the pipe leading to it can contain water or other liquid. The pressure regulator in connection with the parts GG ³ G ¹ works exactly like the centrifugal regulator J. However, other devices can also be used, such as τ. B. those shown in Fig. 9 and 10 ', where the regulator acts horizontally and the position of the pivot point of the lever E ⁱ varies.

This vapor pressure regulator is in FIGS. 6 to 8 in an arrangement similar to that in FIG. 15 The centrifugal regulator shown in FIG. 16 and 16 can also be used in the arrangement shown in FIG can be used without any changes to the construction.

The operation of this regulating device is essentially as follows, with the exception of the arrangements shown in FIGS. 13 and 14. A change in the stress on the machine affects the position of the ring E , which when it is moved causes a rotation of the spindle G , by means of which the control is adjusted. The same movement of the ring E always takes place under the same load, whereas it is not necessary that the adjustment of the control has to be the same under all conditions with the same load, because it is regulated at the same time according to the tension of the steam. For this purpose the coulisse on the spindle G is included in the construction. If the lever arm is short, a given movement of the ring will cause a considerably greater rotation of the spindle G than if it is long. With the secondary regulator, regardless of whether it is a centrifugal regulator or a steam pressure regulator, the changes in the tension of the steam cause the lever arm to change.

If the regulators do not work independently of one another, as in FIGS. 13 and 14, they must be arranged in such a way that at least both of them can act on the control at any time. For this reason the spindle G is set so that the arm G ^{3 is at a} constant angle to the movement of the slide E ² .

The lateral arrangement of the ring E against the shaft G shows that no vertical movement of the slider E ² can occur at any point in the movement of the ring E without the spindle G moving. According to FIGS. 8 and 16, the rod E ^{5 can} not perform a vertical movement without moving the spindle G , which is also the case with the eccentric 2 in FIG. The rod J, Fig. 11, cannot be moved by the regulator / without affecting the expansion valve.

The slide control is shown in FIGS. L is the eccentric on shaft A, L ¹ the eccentric bracket, M the eccentric rod, which is connected to the oscillating arm N. K is a coulisse attached to the shaft by tenons; the same is attached to the side of the eccentric and provided with a slotted arm k . The coulisse is connected to the eccentric L by a pin / on the eccentric bracket, which moves in the slot k . The rotating movement of the eccentric L communicates an oscillating movement to the coulisse k. The expansion slide rod J is connected to the slider j of the coulisse K. Any change in the position of rod J to shaft A changes the slide stroke.

This change is brought about by the fact that the rod J is connected to the shaft H by the rod H ³ and the arm H ^ . As previously indicated, this shaft is rotated by the action of the two regulators on the opposite side of the machine. The rods MM ¹ move the basic slide of the machine, while the rods JJ * move the expansion slide. The rods MM ¹ are connected to the arm N and are guided through it. A slider m ^l is also connected to the arm N by the pin. The rod J ¹ is provided with a loop which surrounds the guide piece m ¹ and in this way forms the guide for the expansion slide rod. '

Figures 20 to 23 show the construction of the slides. The fresh steam is supplied through the opening T ¹ , so it does not enter the steam chamber. The slide, S ¹ is provided with a circular attachment in which a ring, S ^{2 is} attached, which is held in contact with the lid of the steam chamber by a spring s ^{2 in} such a way that a steam-tight guide is produced. The opening of the ring is slightly larger than the area of the inlets and outlets rr and ss, in order to ensure that the slide is in contact. The exhaust steam enters the steam chamber T.

The purpose of the divided canals rr and ss is to secure the largest possible canal area with a small stroke. This device should be better than if the lattice-shaped outlets are installed in the cylinder wall, because the same advantages are achieved here with less space requirement.

Claims (1)

Patent claim: The arrangement of a dynamometric regulator on the shaft of the machine and one Steam pressure regulator, which is not located on the shaft of the machine, in connection with a Control, which is variable and through depending on the action of one of the two regulators the same is adjusted in such a way that the control with the expansion slide is called Machine, as described, is connected, essentially in the by Drawing and description of the characterizing arrangement. In addition 3 sheets of drawings.