DE849192C - Device for speed measurement - Google Patents

Description

Device for speed measurement The invention relates to tachometer units, which for displaying, writing down or regulating the speed of machines or Use apparatus in connection with a force compensation system standing flyweights, displaying, writing down or regulating by pressure changes of a liquid or a gas, for example air, is effected.

Most currently available mechanical and hydraulic regulators are not provided with the appropriate settings, uni them the characteristics of the various types of prime movers used in industry to be able to adjust properly. Systems of monitoring equipment, the appropriate and Independent adjustments included for proper fitting are readily available and provide sufficient control of liquid supplied from a system or gas or energy. However, there is a device for using such a device required for measuring and transmitting the displays of speed changes. A System that lets the pressure of a liquid or gas directly affect the speed responds, part of the adjustment and / or calibration of the instrument is advantageous is thereby simplified. In addition, a system is often desired in which the Fluid is a gas. because it is actuated from the usual device air supply and avoids certain difficulties that exist in hydraulic systems.

The purpose of the invention is therefore to provide such an improved device to create speed measurement, in which the speed measurement is based on the measurement of the Pressure of a liquid or a gas, which is based on changes in speed is highly sensitive. This tachometer unit must have a stream of air or another Generate gas or liquid at a pressure that at the speed of a moving part, for example a rotating shaft, changes, whereby the pressure depends on the flow rate of the The air flow and the supply pressure of the air or the fluid are essentially independent, but preferably the square of the perceived summer or measured speed is directly proportional.

The tachometer unit belongs to the type in which the pressure the liquid or the gas in the power line directly on a flyweights Movable surface acts with a force that depends on the speed of rotation depends on the flyweights, when the device reaches equilibrium has, the pressure of the liquid or the gas of the centrifugal force of the flyweights immediately keeps the balance.

According to the invention is at a speed knife unit, which a flyweight mechanism and a liquid or gas pressure sensitive, the moving abutment contains a balanced element, the liquid- or gas pressure sensitive element connected to a pressure line and are means provided that compared the pressure within the pressure sensitive element to the pressure in the pressure line as a function of the movement of the abutment decrease to a variable extent. Alternatively, springs can be provided, to bias the counter bearing of the flyweight mechanism in one direction to to compensate for the static weight of the flyweight mechanism acting on the abutment.

The invention is described below with reference to schematic drawings explained in more detail using three exemplary embodiments.

Figure I is a view, partly in section, of one embodiment the invention using an air pressure operated relay valve; Fig. 2 Figure 13 is a partial view, partly in section, showing an al> modified device shows to regulate the air nozzle; Fig. 3 is a view, partly in section, a simplified embodiment without a relay valve, and Fig. 4 is a view partly in section, of a third embodiment which is a mechanically operated Relay valve used.

In Fig. 1 of the drawing I represents a base plate in which a Stub shaft 2 is supported by means of ball bearings 3. The shaft 2 can be made by any desired Facility, either directly or via gears, be connected to the property, whose speed is to be measured, recorded or observed or in Depending on the speed of which a mechanism is to be controlled. On the upper one The end of the shaft is a plate l) betw. a cross piece 4 rigidly attached to which with Externally threaded rods 5 are stored in bearings 6. On the bars 5 are weights 7 forming the flyweights in the form of internally threaded ones thick metal washers fastened by means of lock nuts 8. Finger 9 by the levers 5 protrude radially inward, cooperate with a ring 10, which is an annular Has groove that has Edelpaßsitz with the spherical inner ends of the fingers, wherein, when the levers 5 are swung outwards or inwards, the ring is picked up or is lowered.

A vertical tube 11 extends through the ring 10 into a borehole in the shaft 2 and is on the ring via a through a Lid I3 held ball bearing 12 supported.

In the upper end of the tube 11, an insert I4 is attached. From the Described construction can be seen that the tube II and the insert 14 against Rotating can be held while the shaft 2 and parts 4 l) is 10 including be rotated, and that the tube 1 1 together with the ring 10 and the bearing 12 with respect to the fixed base I, shaft 2 and plate 4 perpendicular can be moved.

Optionally, a long coil spring can be used inside the tube 11 15 be arranged. This spring can either be a compression or a tension spring or can be omitted entirely, as will be explained below from the desired dependency depends. In the embodiment shown, the spring is a compression spring, which at its foot end on a resting in the recess of the shaft 2 Ball I6 is supported to rotate between the shaft and the spring enable. The sides and top of the spring align with the sides of the tube 1 1 and with the underside of the insert 14 in engagement. Between the fork parts of the forked upper end of the insert 14 is a lever I7 by means of a horizontal Bolt Ie rotatably mounted. One end of the lever is over a weak one a part of the fixed frame 11 firmly clamped leaf spring 19, and the other end can move according to the vertical movement of the pipe 1 1 free up and down hewegell. The Hel) el 17 can be used as the movable abutment of the flyweight mechanism must be considered. The frame still carries one Luftl> alg 20, the upper fixed plate 2I of which is held in place by a screw 22 is and has openings, which are connected to an annular groove 23 in the frame cover. This groove is connected to an air line 24 via a channel. The lower one movable plate of the bellows rests on the Hel> el 17, with this and the tube 1 1 downwards according to the air pressure prevailing inside the bellows presses. The free end of the handle I7 is flat on the oil side.

An outflow device in the form of an air nozzle 25 is by means of a bracket 26 mounted on the frame F so that its opening is close and parallel to the flat upper surface of the lever, making it easy to change the amount of air flowing out through the nozzle.

The compressed air, preferably from a (not shown) to constant Pressure-regulated pressure source, the line 27 is fed to the pressure source, which is connected to the Pipeline 28 and the nozzle 25 via a throttle point, for example a one Insert 29 having a narrow flow channel or an adjustable throttle valve connected is. A branch line of the pipeline 28 is with a small of Another part of the frame F held l.ufthalg 30 connected. The lower one, movable plate of this bellows is normally up by a spring 31 pressed and is attached to the uliereii end of an operating rod 32, the two with corresponding openings in the upper NVand and in a transverse wall of the Relaisveiiti ls 35 cooperating control valves 33 and 34 carries. These valves are in the Drawings are made conical, but can be made by other known valves Species, for example, by tapering thorns, can be replaced. The lower one Chamber of the relay valve 35 is directly connected to the air supply line 27 and its upper chamber connected to line 36. It's obvious. that the lower Valve 34 regulates the flow of air from the lower chamber to the upper chamber, while the valve 33 allows air to escape from the upper chamber through the upper \ N'an (l regulated into the environment. When the rod 32 is pushed completely down is, the valve 33 sits on its seat, and the valve 34 is fully open and thereby lets the air (lrucli in line 36 rise to its maximum value; when the rod 32 is fully raised, the valve 34 is closed and the valve 33 fully opened, whereby the pressure in the line to zero, i.e. H. to the ambient pressure. The pressure in the line 36 is accordingly the position of the rod 32 as determined by the air pressure in the bellows 30 and the spring 31 is determined to assume a value in the middle between these two extremes. The maximum pressure should be equal to the pressure in the line 27 in the case in which the receiving device, for example a display, writing or control device, keiiie Takes air. In many applications of the device, the receiving devices leave however, a small amount of air is constantly flowing out l) zxv. outflow, and the maximum Pressure will be slightly less, this being from that of the narrowing between the polish and lower chamber of the relay valve depends on the pressure drop resulting from it.

Line 3 (> is connected to pipeline 24 and a branch line 37 connected. The branch line 37 forms the liquid or gas power line and can be used with a pressure sensitive device of any type, for example the pressure gauge 38, which is either in units or revolutions is divided per minute.

In operation, the shaft 2 with the speed of the to be monitored Mechanism or a speed in constant ratio to this rotated, and the tube 11 is supported by the spring 15 and the centrifugal force of the weights 7 pushed up. The upward pressure is affected by the weight of the vertical moving parts including the lever 17 and that of the line 27 via the Relay valve 35 and pipes 36 and 24 supplied with pressurized air Against bellows 20. When equilibrium is established, the downward balance is equal directed force of the bellows exactly the purely upward pressure of the pipe 11 off. As this upward force corresponds to the air pressure in the bellows and in the Lines 24 and 37 is exactly proportional, it is evident that the one of the Pressure gauge 38 indicated pressure is the purely upward pressure of the pipe 11 will also be directly proportional. Through this facility one weighs the longitudinal pressure of the flyweight mechanism or brings it through the air pressure directly into equilibrium and uses this air pressure for actuation or control any receiving device.

The function of the device is as follows: Suppose the device is in operation and the rod 32 in the correct position to the above-mentioned equilibrium condition to manufacture.

Furthermore, assume that the speed of shaft 2 increases. The one doing it The resulting increase in the centrifugal force of the weights destroys the balance of forces and causes the pipe 1 1 to rise slightly free end of the lever I7 raised and closer to the fixed mouth of the nozzle 25 moves, which reduces the amount of air flowing out of the nozzle constantly will. With this, the pressure drop across the insert 29 is reduced, and consequently the pressure in the bellows 30 increases; the bellows 30 pushes the rod 32 and that of it carried control valves down and thus increased in the manner described above the pressure in the pipe 36. This increased pressure is the fluid or Gas pressure line 37 and also transmitted to the main bellows 20 until the force of the bellows again compensates for the purely upward pressure of the pipe 1 1. As the pressure in the main bellows 20 increases, it slightly exceeds that which is directed upwards Pressure of the tube 11 and pushes this down; thereby becomes that of the free The plate formed at the end of the lever I7 is moved away from the nozzle 25 until a new equilibrium is reached is reached at a pressure which is higher than the original equilibrium condition.

If the speed of shaft 2 drops, there is an equilibrium, at a lower air pressure in the line 36, the main bellows 20 and the air power line 37 adjusts. If not constantly blowing air receivers are used, the air pressure in the system is caused by the escape of air through the upper opening in the relay valve, past the valve 33. In this case it is necessary to make this opening sufficiently large do, to allow the necessary amount of air in a timely manner can flow out of the bellows and the line 37.

If the volumetric content of the air line is large, 36-37-24 is It is desirable to use air venting devices at all times or an outlet opening 39 to be provided.

It is also possible to provide a simpler relay valve that only the control valve 34 for controlling the flow of the high pressure Has air, and when the pressure in the system needs to be reduced to to achieve equilibrium at a lower pressure for the air release to rely on the openings 39 or the air consumption of the receiving device.

The centrifugal forces of the weights 7 exerted on the tube The force acting in the vertical direction is the square of the angular velocity and the distance from the axis of rotation and the center of mass of the weights proportional. In the device described, the removal of the weights from the axis of rotation can be kept substantially constant, that is, it is possible for the device to build so that the tube 11 at different equilibrium positions only by very small amounts, for example several hundredths of a millimeter, in vertical directions Direction moves and the radial displacement of the flyweights during this movement is correspondingly low.

In a specific embodiment, a device, where the center of mass of the weights is about 25 to 32 mm from the axis of rotation is to be achieved that when the shaft speed changes from, for example 300 to 700 rpm this radial distance changes only by 0.12E5 mm or even less.

This change is only 0.40 / 0 of the radial distance and therefore will cause a negligible deviation in centrifugal force from the value which is proportional to the square of the angular velocity.

As was stated earlier, it is vertically upwards against the Main bellows 20 directed force is the algel> raic sum of the following effects: the weight of the vertically moving parts, including one of your fingers 9 transmitted downward or downward force, which, if present, originates from the static load of levers 5 and weights 7; the force of the spring 15 and that transmitted through the fingers, caused by centrifugal forces perpendicular force.

I) he pressure inside the bellows is directed purely upwards Force precisely proportional, so the pressure is represented by an equation of the following form can be: pressure = Kl + K2 + K3V2.

Herein is: A, a constant that corresponds to the purely ollen-directed, is proportional to the force resulting from the static weight of the vertically moving parts is, usually a negative number; K2 is a constant that of the upward Force of the spring 15 is proportional, in the case of a compression spring, as in the example, a positive number; K3 is a constant that corresponds to the mass of the flyweights, the lock nuts 8 and the lever 5 is proportional and also on the design of the flyweight mechanism depends; V is the angular velocity of shaft 2.

The constant Kl is zero when the flyweights are in an equilibrium position in a certain Al> stand from the axis of rotation beyond its pivot bearing 6, so that its static weight pushes the pipe upwards with a force that is exactly is equal to the weight of the other vertically moving parts; when the weights are still further from the axis, A-1 is a positive number.

If it is desired that the pressure is the square of the speed is exactly proportional to wave 2, obviously Kl and A-2 must be the same and hold opposite signs.

In the usual case in which K1 is negative, K2 must be positive and a compression spring 15 may be provided.

This is the embodiment as shown in the drawings is. However, if Kl is positive, a tension spring should be provided. Finally can if K1 has the value zero or the square of the speed prol) ortional Al> readings are not required, the spring 15 can be omitted. For accurate work is it is desirable that the spring force at the various equilibrium positions remains essentially constant; for this reason the pen should be made long be, then the compression or elongation during operation is a negligible ratio of their length. This is done by that the spring, as shown, is installed within the elongated tube 11. The stream of air flowing out of the nozzle 25 exerts a slight downward direction Pressure on lever 17. This low pressure can be included in the K1 factor and is assumed to be constant.

Numerous modifications can be made in the arrangement and construction think of the parts without departing from the spirit and scope of the invention. For example, the nozzle 25 is not required to be narrowed by the lever I7 will; its opening could change the amount of air flowing out by one of cone tip carried by the lever, or the nozzle could be controlled by a Disc or other spinning with part of the flyweight mechanism Part to be narrowed. These modifications are shown in Figs.

In Fig. 2 the nozzle 25a is provided by a mounted on the lever 17a Cone tip 40 controlled, the nozzle and the lever in the same way as the Nozzle 25 and the lever 17 of FIG. 1 are in communication.

Fig. 3 not only shows the modified arrangement for the constriction the air nozzle, but also a simplification of the velvet Device in which the relay valve is omitted. In this figure are the base plate 1, shaft 2, plate 4, lever 5, pivot bearing 6, weights 7, lock nuts 8. fingers 9, Ring 10 and tube 11 as described in FIG. 1, arranged. The lid 13b, which rotates together with the plate 4, extends upwards to the Height of the lever 5 and can be used as part of the movable abutment of the flyweight mechanism to be viewed as. In a part of the frame F, an air nozzle 25b is supported, and so that its opening is close to and just above the flat upper one Surface of the lid 13b rotating with the plate 4 is located. The lid 13b cooperates with the nozzle opening in its upward and downward movement and regulates the outflow of air.

The upper end of the tube 11 carries a spring, if desired, like spring 15 of Fig. 1, retaining insert 14a, which is attached to a frame F by means of screw 22 and, as described above, with the line 24 connected bellows 20 is engaged. Air under constant pressure. how it is supplied from a pressure-regulated air source is through the conduit 27 and fed through a fixed or adjustable constriction, such as via an adjustable throttle valve 29h. The throttled air becomes the Bellows supplied via line 24 and nozzle 25b via branch line 28b; these lines are also directly connected to the air power line 37b, which, as described above, with a displaying, writing or controlling device, with or without air blow-off, can be in communication.

When the device is in equilibrium, it becomes pure upward pressure of the tube 11 from the downward force of the Bellows 20 exactly balanced. In this position, the air flows out of the nozzle 25b at such a speed that the occurring at the constriction 29b Pressure drop in line 24 and bellows 20 causes the required pressure. It should be noted that this pressure drop also depends on the speed with which the air flows out of the system at the receiving device. If the The rotational speed of the shaft 2 increases, the upwardly directed one on the pipe 11 increases acting force, and the tube 11 moves together with the ring 10 and the Lid 13b upwards. As a result, the opening of the nozzle 25b is blocked, the air outflow is reduced and, as a result, the pressure drop across the constriction 29b is reduced. Through this the air pressure in lines 37b and 24 is increased and the bellows 20 moves that Tube 11 and cover 13b down until a new equilibrium is reached has set higher pressure. Similarly, if the speed of rotation of the shaft 2 decreases, the air flow from nozzle 25b increases, and the device takes a new one Equilibrium at a lower pressure. To facilitate regulation, it may be desirable to have an adjustable or fixed auxiliary throttle in branch line 28b 41 to be provided. This means that the pressure at the nozzle is lower than the pressure in the Lines 24 and 37b and less affected by changes in this pressure. the Throttle point 41 is, however, left to the free choice.

Fig. 4 shows a modification in which the Kelais valve mechanically is operated. In this embodiment, parts 1 to 24 can be used as here be described in Fig. I, built and arranged. The frame F carries a through a console 43 attached relay valve 42, the middle chamber by a Channel 44 is connected to the groove 23 and the line 24. The relay valve has two Transverse walls, which are provided with openings, which are conical, on a common Actuating rod 47 attached control valves 45 and 46 cooperate. The pole goes through a large opening in the underside of the valve housing and is with a fixed on the free end of the lever 17 plate 48 in engagement. The top division of the relay valve is through a line 27c under constant Pressurized air supplied. The rod 47 can be spring loaded if desired However, gravity and that between the three compartments are usually sufficient air pressure of the valve to engage the rod with the plate 48 keep.

The line 24 serves as an air power line and can, as described above, connected to an indicating, recording or regulating device of any type be.

It can be seen that the top section of the relay valve, d. H. the compartment above the valve 45 has the pressure of the air supply; the lowest compartment below the valve 46 has the ambient pressure; and the intermediate division becomes one of the vertical position of the valves 45 and 46 have dependent intervening pressures. Such relay valves are easy to build in such a way that they achieve a maximum, by mounting the control valves certain stroke of the rod 47 from a suitable low height, for example about 0.1 mm.

In operation, the one acting on the pipe 11 is directed purely upwards Force, as described above, by the downward force of the bellows 20 balanced. When the speed of the shaft 2 increases, the tube 11 and the plate 48 and thus the rod 47 is raised by the amount of air blown past the valve 46 to reduce and the influx of the amount of high pressure air to the Valve 45 to enlarge over. This will reduce the pressure in the intermediate Chamber and consequently also in line 44, bellows 20 and the air power line 24 increased. The bellows then presses the pipe II downwards until a new equilibrium is reached is reached at a higher pressure in the line 24. Goes in a similar way when the speed of the shaft 2 drops, the rod 47 goes down. and it represents a new equilibrium at a lower air pressure.

The new one resulting from a change in the speed of the shaft 2 Equilibrium occurs in all the versions described with new positions of the Tube 11, which is somewhat different from the previous equilibrium positions so that, strictly speaking, the device is not a null device. Practically however, the device is a null device because the magnitude of the movement of the Rohres and the radial change in position of the flyweights are so small that they are neglected can be.

Although the best results are obtained by having a Gas or liquid supply regulated at constant pressure is used to point out that this is not essential because the pressure of the liquid resp. of the gas in the pressure sensitive device always directly with the centrifugal force is in equilibrium and for the same speed of rotation of the flyweights the pressure in the power line is therefore always the same.

The main disadvantage of using an air supply with fluctuating Pressure is that the movable abutment of the flyweight mechanism at a given constant speed at equilibrium a slightly different vertical Position as the air pressure changes. This results in a very small change in the distance of the flyweights from the axis of rotation and thus at equilibrium, slightly different pressures in the air line.

While in the description of the invention on the use of Air is referred to in the system, it is understood that other gases or Liquids can be used.

While the liquid or gas pressure sensitive element is a bellows was carried out, it is obvious that any equivalent device, such as a piston operating within a cylinder containing liquid or gas its place can be set.

PATEN.TANSPROCHE: 1. Tachometer unit with a flyweight mechanism, a movable abutment and a liquid or gas pressure sensitive, the movable abutment has a balanced element, characterized in that that the pressure-sensitive element via a throttle point (34, 29b, 45) with a Pressure line (27, 27C) is connected and also with a Druckmittelaustritteinrichtungubg (33, 25b, 46) is in prevention, the outlet opening of which is corresponding to the Movement of the movable abutment changes.

Claims (1)

2. Tachometer unit according to claim I, characterized in that that the throttle point in the pressure line is formed by a valve (34, 45), its opening in ale depends on the movement of the abutment (I7) will be changed. 3. Tachometer unit according to claim 2, characterized in that that the pressure medium outlet device also by one by the movement of the Abutment controlled valve (33, 46) is formed. 4. Tachometer unit according to claim 3, characterized in that that the two valves (45, 46) are interconnected and from the movable one Abutment (17) of the flyweight mechanism can be controlled directly. 5. Tachometer unit according to claim 3, characterized in that that the two valves (33, 34) are interconnected and by a second pressure-sensitive element (30) are actuated. via a throttle point (29) is connected to the pressure line (27) and also with a pressure medium outlet nozzle (25) is in connection, which is directed against the movable abutment (17) is that she is throttled by this. 6. Tachometer unit according to claim I to 5, characterized in that that one the abutment (17) of the flyweight mechanism biasing in one direction Spring (I5) is provided, with this on the abutment a substantially constant, the static weight of the flyweight mechanism acting on the abutment exerts equal and oppositely directed force. 7. tachometer unit according to claim I to 6, characterized in that that the movable abutment of the flyweight mechanism is rotatable at one end mounted lever (17), the middle part of which is on a pressure-sensitive Element-forming bellows (20) acts and its free end directly or indirectly controls the pressure in the bellows.