DE41416C - Facility for measuring or. Registering mechanical force or indicating work done - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 42: Instruments.

CARL DIHLMANN in BERLIN.

work done.

Fatentirt in the German Empire from June 14, 1887.

The present invention relates to a device by which the from any The force transmitted to a power source is measured in its respective magnitude and this magnitude can be registered continuously. Through this facility, the Sum of the work done automatically by any engine at any given time are displayed. '

For measuring performed or transmitted force respectively. Work is used in In practice only the braking process, which is cumbersome and large Forces can no longer be carried out; it also only permits the determination of the to a certain point in time performed or transferred power respectively. Work, but not that Register different working quantities which are to be transferred one after the other nor the summing or counting of them during a definite period of time. Various apparatuses devised for this latter purpose z. B. Morin's dynamometer, have their cumbersome construction and Not able to become naturalized in practice for the sake of handling.

In order to avoid these inconveniences, I have invented the following apparatus, which in the essential, like Morin's, consists in the fact that the force resp. Transferring workers Parts, as: pulley, gearwheel, coupling, shaft etc. on the one hand and coupling, Shaft, etc., on the other hand, are elastically connected to one another in such a way that one of these forces more or less due to the force to be transmitted during the walk proportional displacement or twisting of these parts with respect to one another is, in order from the size of this twist, respectively. Shift to the size of the transferred Power and, if the speeds respectively. Revolutions per second or minute are known to the amount of assigned work to close. This apparatus i can also be brought into connection with a device which is used for the Size of the twist resp. Displacement of the individual parts during the course measure or the consecutive twisting or. Displacement quantities to register or count.

The above-mentioned elastic connection is essentially carried out using a threaded piece bb, FIGS. 1, 2 and 3, the mode of operation of which will be explained by the following examples.

In Fig. Ι AB represents a section through. a pulley (or clutch or gear wheel or the like), the movement of which is to be used for the measurement. The hub aa of this disc is provided with a nut thread into which the threaded piece bb fits. The latter is on the driving respectively. The driven shaft is attached in such a way that the shaft does not rotate, but can be displaced in the longitudinal direction of the shaft (i.e. about

using a keyway and feather or a square or the like). If a force is now exerted on the periphery of the pulley AB in the direction of a tangent (which, when the belt is in operation, is the same as the difference between the two-sided belt tensions), the pulley first tries to turn and, if the above-mentioned thread turns right or left, it tries to move move right or left. In order to prevent such a shift to one side (for example to the left), the sleeve dd, against which the hub of the disc rests, is firmly connected to the shaft. The next consequence of the rotation of the disc AB is that the piece bb must shift to the right; here it presses against a spring FF pushed onto the shaft, which at its opposite end abuts against the fixed sleeve ee. The spring is now compressed until the force acting on the periphery of the disc AB is in equilibrium with the counterforce exerted on the spring, whereupon the rotation of the shaft will begin. Exactly the same game in the opposite sense occurs when the moving force occurs on the shaft instead of the disk. From the magnitude of the displacement ■■ of the piece bb one can now see that which occurs at the periphery of the pulley. Force and from this, if the speed of the disk periphery is known, inferring the amount of work transferred.

Fig. 2 shows the same device applied to shaft couplings; here half a dome h ^{l is} firmly connected to one end of the shaft, while the other half dome /? ² in place of the pulley shown in Fig. Ι BEZW. whose hub occurs, while bb is again the sliding threaded piece. Of course, the two half couplings can also be made from a single piece.

The magnitude of displacement of the piece bb to determine during the transition, is either an immediate reading device or a transmitting by a lever mechanism bb movement of the threaded piece. In the former case, the same can be arranged as described with reference to FIG. This arrangement consists of the tubular extension χ, which is firmly connected to the piece bb and has such a division on its surface that at certain distances individual lines or lines running back into themselves. Circles are cut perpendicular to the axis of rotation, the relative position of which is read directly against a mark firmly connected to the sleeve ee or the hub α α. In the second case, the reading device. be arranged so that the displacement of the threaded piece bb is transmitted by a lever mechanism and made visible, as shown in Fig. 2, for example. Here f ^l f ^{2 form} the guide rings; if bb is now shifted towards ee , i.e. if f ^l approaches f ² , then the pointer ^ ¹ ^ ² ^ " ³ is rotated by the movement of / ¹ ο ^ ¹ about its fulcrum ^ ² , and from its deflection the Determine the displacement of bb.

A simplification of the construction indicated consists in that the piece bb is firmly connected to the shaft, so that instead the pulley (or gearwheel, clutch, etc.) is shifted to the side under the action of the external force, whereby only this is taken into account it is to be assumed that the hub α α rests directly or with the aid of an intermediate piece against the spring FF and causes it to be compressed.

In all the cases mentioned so far, as shown in Fig. Ιa, for example, instead of the spring FF , a lever device y ^l jr * with counterweight G can be used, the latter being lifted by the displacement of the threaded piece bb. The transferred force can then be determined from the degree of this elevation. Determine the work and read it off with a pointer y ³ on a correspondingly attached scale.

Instead of a pressure or A tension spring, such as that shown in FIG. 1, can also be used as a torsion spring, as illustrated, for example, by FIG. 1b. The mode of operation here is as follows: The sleeve dd carries an extension mm which is connected to the hub α of the pulley in such a way that the pulley AB can rotate against the hollow piece α α , but cannot move relatively against it. The torsion spring FF is firmly connected with one end to dd and the other to the hub Λ (or the clutch or gearwheel or the like). If a force now acts on the disc AB , the former rotates on the shaft until the torsion spring FF has suffered the rotation corresponding to this force, and the rotation of the shaft will begin. Simultaneously with the rotation of the disk AB , the threaded piece bb is displaced from its original position, and the strength of the acting force can again be determined from the extent of this displacement.

If the threaded piece bb is firmly connected to the shaft and the disc etc. is slidably placed on the same, the spring F is both on train and respectively. Pressure as well as torsion and the displacement of the threaded piece bb will again provide a measure for the acting force. By analogous connection of dd with bb and corresponding

Change of the points of application of the spring FF, as well as by using several springs or a combination of one or more pressure respectively. Tension or torsion springs, also by using clutches, gears, etc. instead of the disc AB , a number of other arrangements can be achieved in which indefs always the same result is intended, namely the displacement of the threaded piece bb respectively. the hub aa ü. the like. (of the associated disc, the gearwheel, the clutch, etc.), in order to serve as a measure of the force that is currently acting.

All the constructions given so far had only the purpose of reducing the power or Measure work at any given moment. But one can use such a dynamometer (if the device for the direct measurement of the displacement of the threaded piece bb is omitted) with a recording device which, either with a certain number of revolutions of the shaft or evenly through a clockwork, moves the amount of rotation at certain time intervals respectively The displacement of the elastic parts relative to one another is recorded, or connected to a device which, on a counter, shows the sum of the twisting resp. To read off the displacement quantities of the individual parts of the elastic connection directly, and thereby to draw a conclusion as to the work transferred. The recording apparatus used in the first case has the task of continuously registering the respective magnitude of the displacement of the piece bb , in order to recognize from the successive recordings the working quantities transferred during a certain period of time and during the individual parts of the same. The same can be carried out according to any system or according to any of the known constructions.

In Fig. 2, for example, a paper strip (as indicated by dotted lines) is used for this purpose. passed in front of the pointer of the lever mechanism, in such a way that this pointer is its individual positions marked on the paper strip.

Around . for the latter case, the sum of the individual Verdrehüngs- respectively. To make displacement quantities visible by means of a counter, I use a construction, consisting essentially of a cone, which rotates around its axis uniformly by means of a clockwork or proportionally to the main shaft by means of transmission and shifts in the direction of its axis proportionally to the threaded piece bb , in connection with a wheel pressing against the outer surface of this cone, the axis of rotation of which lies wholly or approximately in the same plane with the axis of the cone, so that this wheel also rotates as a result of the friction with the cone, and the faster the more the cone The cone is moved as a result of the displacement of the threaded piece bb against the wheel, in order to determine the number of revolutions of this little wheel, which is noted by a counter, the performed or. to determine the work assigned, as shown in FIG. 3, for example. Here, k is the ρ on the shaft q fixed cone y by the guide ¹ / is occasioned μ ^1, of the displacement of the threaded piece bb to follow, and at the same time by the belt rrr in revolution offset is that in proportion to a speed the main shaft; st is the small wheel with the axis ν n> pressed against k , the latter being connected to the counter through a universal joint at point ν. With appropriately selected transmission ratios, the meter-kilograms and / or. Read hourly horse forces.

Is the twisting of the elastic parts resp. the displacement of the piece bb is not exactly proportional to the performance respectively. transmitted force, it can be achieved by a corresponding redesign of the outer surface of the cone k, which in the case of non-proportionality must not be a pure cone, but a surface of revolution more or less deviating from the conical surface, that the revolutions of the little wheel st are exactly proportional to the sum of the transferred forces respectively. Working quantities.

If the angle at the tip of the cone k increases by up to 180 °, the cone becomes a disc which can be used for the same purpose.

Claims (1)

Patent claim: A device for measuring or registering mechanical force or for displaying work done, in which a device that is displaceable on the shaft or fixed immovably on the same and with an external one. Threaded threaded piece bb in the hub α (or the like) of the force BEZW. Work receiving or delivering and attached BEZW on the shaft. displaceable pulley A (or clutch or gear wheel or the like) engages, and in which by one or more pressure respectively. Tension springs, or one or more torsion springs FF, or a combination of compression and torsion springs or a loaded lever mechanism ^ ¹ ^ ² the threaded piece bb respectively. the associated pulley (gear, clutch or the like) in his or their normal position is pressed, so that the linear displacement, which the threaded piece bb respectively. the displaceable pulley (clutch, gear or the like) in the .Tebetriebung of the force respectively. Work suffers. gives the measure for the quantities to be determined, which measure either: a) can be read directly on a scale at every single moment (as in Fig. Ι for example shown) or by a lever BEZW. Transferring the pointer train and is made recognizable on a scale (as in Fig. ι a and 2, for example shown); or b) on one in front of a point or the pointer of the shifting part continuously. the moving disk, drum or tape of a recording device or the like is continuously recorded (as shown in FIG. 2, for example); or finally
by transmitting the linear movement of the threaded piece bb to a rotating body K (as shown in Fig. 3, for example), which is set in rotation at the same time by the rotating parts (or by a special clockwork or the like), whose line of production is designed accordingly, and which has a second , appropriately designed and seated on the first shaft of a counter body of revolution st with the circumferential speed determined by the respective position and the associated radius of the first body of revolution, influences the number of revolutions of the second body of revolution st in such a way that the total of the work quantities performed by the counter during a any time period is specified. For this purpose ι sheet of drawings.