DE104522C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 42: Instruments.

Patented in the German Empire on May 28, 1898.

The present invention aims to measure BEZW. Reading the through a Open belt transmission transmitted mechanical work or power, and indeed should not only the mechanical work can be determined, which at the time of reading by the Transmission works, but it should also be possible to read the mechanical work, which on average are transmitted from the transmission over a longer period of time - weeks or months has been, the transmitted force or the speed may have been subject to any changes.

For this purpose, the pulled and pulling belt ends are either brought together by means of two tensioning rollers S and S ₁ (Fig. 1 and 2), the mutual distance of which is invariable, in the direction normal to the connecting line of the two pulley centers O and O ₁ (Fig . 1) or stretched out of one another (Fig. 2) and the tensioning roller centers are made easily displaceable by means of a suitable guide normal to the aforementioned connecting line.

In Fig ι., The guide is indicated as a right straight guide, in Fig. 2, the Spannroljlenmitten be by means of the axes and <fj rotatable swing d e and e out _x, in Fig. 10 d and _ά λ in a point d ₂ united.

In the previously known devices, which are used to measure the work transmitted by the belt drive by means of tensioning rollers, as previously described, the tensioning roller pair is held in the central position, and the excess force with which the pulling belt pushes the tensioning roller pair to the side of the pulled one becomes , harnessed for the effect. In the present invention, the pair of tensioning pulleys is not held in its central position; rather, provided that it is well balanced, e.g. by the weight gg ₁ , as a result of the greater force that the tensioned belt exerts on its tensioning pulley, it will move to the side of the untensioned belt, and the measure of this deviation is used to determine the work assigned. The way in which this is achieved is shown in the following.

Ν denotes the belt speed, T ₁ the tension in the pulling, T ₂ the

DID

pulled belt, T ₀ = - the belt tension in the state in which no force is transmitted, and P = T ₁ - T _{2 is} the transmitted force, so

i. L = Pv

is the work performed at each point in time, and if t is the time and s is the distance that the belt has covered in time t , then is

2. = \ Pds

the work transferred in the time in which the belt has covered the distance s .

In the device which forms the subject of the invention, the determination of P at the time t must therefore be expressed and also s, but it must also be the addition

P ds

cause.

Referred to (Fig. 11) χ, the divergence of the roller pair normal to the line joining the two Riemscheibenmitten OO _1, it follows on the basis of Fig. Io and ι ι with the designations in them for sufficiently small a smaller neglecting quantities second order when even with q the force with which the two rollers S and S ₁ try to change their mutual distance in the state of the gearbox in which no work is being transmitted, the balance of the forces acting on the roller pair:

3 ·

a - χ

COS β

lax)

Vb

2T _n

- good

a + χ

cos β

= ο

α cos β

cos β

From both it follows, if you bet: R

5-

A =

Yb

tg β cos β

6. P = q

a ¹ cos ² β

X-

I ^a λ ^X Λ

ι + -rA _Γ Α

b from

or in general, under C ₀ understood a constant,

'In this equation f (x) and q are variable quantities, namely f fxj because χ changes continuously, q because the tension with which a belt is placed over two pulleys never remains constant, but becomes smaller, i.e. every belt becomes slack over time and needs to be retightened.

In the one to represent the work referred to in equation 2 and transferred by the gearbox

P ds

The apparatus shown in FIGS. 3 to 7 and denoted by Z in FIG. 2 is used, namely the conoid X ₁ takes into account the variable term f (x) and the cone κ. ₂ the variable q, as will emerge from the following.

According to the drawing, FIG. 2, the worm shaft 0 is driven by one of the two transmission shafts by means of a belt which is placed around the pulley (FIGS. 2 and 4). As a result, the number of revolutions U _{1 of} the shaft I (Fig. 3) is proportional to the distance s that the main belt has covered in time t .

8. S = C ₁ W ₁ and ds - c ₁ du ₁ .

where C _{1 is} the proportionality coefficient.

^{The shaft I 1} (Fig. 3) with the conoid K ₁ is axially displaceable in the shaft I in such a way that from the pair of rollers SS ₁ (Fig. 2) or from a point of one rocker e , i.e. proportional to the roller deflection χ das Konoid K _{1 is} moved up and down. The shafts I and I ¹ are coupled to each other for rotation by the driver τ (Fig. 3) and the transmission of the deviation χ of the roller pair occurs in the embodiment shown in FIGS. 2 and 3 by means of the rod m and the lever η and W ₁ , while the lever W ₂ serves or can serve for balancing and possible attachment of a liquid cataract for the purpose of calming the otherwise unavoidable fluctuations in the movements.

From the shaft I ¹ (Fig. 3, 4, 5 and 7), the shaft II is mediated by the friction wheel Jc ₁ , _{which is dragged along by the conoid Ji 1} and which is mounted in the rocker γ _λ, which is rotatable about II and its rotational movement mediates the two spur gears ε and ζ ₁ on the shaft II, offset in rotation. The spring η ₁ prefers the friction wheel Ji ₁ against the conoid K ₁ .

M ₂ denotes the number of revolutions that the shaft II has covered in time t , T ₁ the radius of the friction wheel Zc ₁ and P _{1 the} radius of the conoid K ₁ that drives the friction wheel _{Jc 1} at time t , so is

you = - ^ - you.,.

pi

In the same way as wave II becomes wave I, wave III becomes wave III Shaft II driven (Fig. 3, 4, 5 and 6). The axially displaceable cone on the latter, κ,

drives the friction wheel Zt ₂ , which is in the rocker γ rotatable about the shaft III. _{2 is} mounted, with the intermediary of the spur gears ε ₂ ζ ₂ , and the spring rj ₂ prefst the friction wheel k ₂ against the cone K ₂ .

If M _{3 denotes} the number of revolutions of the shaft III in the time t, then it is

10.

you ₂ - ^ -

pi

if r _{2 is} the radius of the friction wheel Ar ₂ and p _{2 is} the radius of the cone K ₂ that is active at time t. By means of the fork λ (Fig. 3 and 9), which can be moved up and down on the square μ ^{1 of} the spindle μ _{, every radius p 2 of} the cone κ ₂ can come into effect. This is indicated on the scale (Fig. 4) by means of the slide v, which is set by means of the angle lever ξ moved by the fork λ so that, when the arrow of the slide on the scale is on I, the largest radius p ₂ ' , and when the arrow is on 0.5 of the scale, the radius 0.5 P ₂ ^{1 is} in effect.

According to equations 8, 9 and 10 is

τ
11. ds = C ₁ d U ₁ = C ₁ - ^ - d U ₂ =

C ₁ ^ - -du _& ¹ Pi Pi

and according to equations 2, 7 and 11 the work transferred in time t:

12. A- = \ Pds -

r ^{qf (x)} you

The force q is proportional to T ₀ according to equation 5, ie proportional to the belt tension, which, as already mentioned, cannot itself be changed, since every belt becomes slack over time and has to be retightened. It is measured by a spring w (Figs. 2 and 8) which is connected in the connection between the two rollers S and S _{1 in} such a way that it serves to measure the force q without changing the distance between the rollers.

Fig. 8 shows the connecting link of the two rollers which, in the selected embodiment, connects the rockers e and e _x to one another. The holding connecting link forms the spindle /, which is rotatably fastened at one end in the traverse \ by means of two nuts firmly screwed onto a sleeve, at the other end with the nose adjusting ring j ^ abuts against the inner surface of the frame K and by means of the bolt z, the engages in a screwed groove of the spindle /, is locked. The bolt i can be triggered at the button j. If after the release the force of the spring outweighs the belt force q in the state P = 0, ie if no force is transmitted, a clearance will be created between the nose collar y and the inner surface of the frame K , so that the nose υ will be free. One can then screw back the nut h on the square of the spindle / by turning it, which is held against rotation by the scala rail φ, and thus tension the spring w less, that the nose ring ^ again touches the inner surface of the frame K , the interlocking the lugs σ prevent further rotation and the locking is carried out by the pin i . In this condition, the spring force and the belt force are in equilibrium, and the latter is measured by the former.

If ^ _{0 is} the spring force for the scala point 1 of the scale (Fig. 8) and if the spring force is reduced by half, i.e. to 0.5 q ₀ , by screwing back the nut h up to the scala point 0.5, then if one goes through regular control ensures that the slide ν (Fig. 4) and the nut h (Fig. 8)

on the same number of the scale is the fraction -

be a constant in equation 12, because if q z. B. has decreased to half, then p ₂ will also have half the value and because of the proportionality ratio between load and deflection in a spring the immutability of - = - will also be retained in all other points.
P2

Just like the break

is also the

fracture

.Pi

constant when one

makes f (x) proportional, that is, gives the conoid a form which is determined by the equation:

'3-

1 + ^ A-b

^ ₁ -ab

and ensures that in the state in which no force is transmitted (P = o; x = o), the friction wheel ^ _{1 works together} with the tip of the conoid K ₁ . The stop pin £ ■ prevents this limit position from being exceeded.

If one calls the constant number in equation 12

S (x) 1 14th C ₀ C ₁ T ₁ T ₂ ^ -! * - = qc,

Pi pi
so will

, 5. A =

q ₀ is the spring force of the spring w, corresponding to the scale number ι, M ₃ is the number of revolutions of the shaft HI in the time on which the measurement is based, which is noted on the counter, which is indicated in FIG. 3, and c is a constant that is composed of the various dimensions, etc. and must be determined for each apparatus.

If the constant c is arranged in such a way that A is determined in hours horses, one only needs after any arbitrary time - days, weeks, or months - to multiply the constant, which is noted on each apparatus, by the number given by the counter to keep the work that has gone through the transmission in hour horses. Is z. B. the constant 6 and shows the counter in 600 hours, equal to 60 working days of 10 hours each, the number 2500, then on average = 2 horses through that

. 600 ^D

Gear gone.

To determine the mechanical performance at any given time, one has to use the Equations 1 and 7:

= Pv = c _o qf (xj V = c _o q _o ~~

v.

is the one on the scales in FIGS. 3 and 8

standing number, the belt speed ν is known, the constant C ₀ q ₀ is also noted on the device and f (x) can be read off by means of the pointer w on the associated scale (Fig. 3). L is thus obtained by multiplying the constants C ₀ ^ ₀ ν by the number given by the pointer ω and by the number given by the slider ν (Fig. 3).

The essence of the invention consists in the application of the movable tension pulley pair, which respectively with different magnitudes of the transmitted force. Work another evasive assumes, and that in conjunction with the spring in the link between the two tension pulleys, the means of determining both the instantaneous Power like the work that has gone through the gearbox over a long period of time.

The measurement of both, i. H. the current performance as well as the longer time completed work, is done by means of a conoid with associated friction wheel, and the gradual changes in belt tension are taken into account through the arrangement of a cone connected to the gearbox of the apparatus with the associated Friction wheel.

The spring used here has the purpose of measuring the tension, with which the belt is independent of the force to be transmitted, d. H. in the state in which no power transmission takes place on the pulleys, is placed. With the so far known apparatus in which a spring is used, this has a different one Purpose.

Claims (2)

Patent Claims: ι. A working knife for belt drives or gears using flexible straps, ropes, Cords and so on, characterized by the arrangement of one of the straps and so on each other or tensioning, freely movable pair of rollers, which in the power transmission deviates to the side of the loosened belt part and its deviation to determine that of the gear transmitted force respectively. Work serves. 2. The arrangement of a spring in the link between the in the first. Claims characterized tensioning pulleys for The purpose of determining which is to hold the tension pulleys in their mutual position Power in the event that power transmission does not take place. 1 sheet of drawings.