DE383C - Automatic viscous fluid volume measuring apparatus - Google Patents

Description

1877.

Class 42.

ROBERT PZILLAS in BRIEG. Automatic thick-fluid-volume-mersapparatus.

Patented in the German Empire on July 21, 1877.

1. Fig. Ι left a section along the length,

right, side view.

2. - 2 front view.

3rd - 3 left cut across, right

Grundrifs.

4. - 4 to 7, different positions of the

Steering.
The whole apparatus consists essentially of:

1. From the Mefsgefafs A.

2. From the controller B.

3. From the counter C.

i. The Mefsgefafs A. This forms a cylinder α of 2.10 dm diameter and 4.21 dm length made of cast iron with a brass insert, in which the piston b, Fig. 1, 3, 5, 7 of 1.284 dm in height intended for cleaning - and slides, but always stands back by 2 mm from each end of the cylinder, so that then the entire length of the cylinder is only (421 - 128.4 - [2. 2] mm) = 288.6 mm. With a diameter of 2.10 dm, this length corresponds to a content of 10 qdm = 10 1. At the cylinder α, Fig. 1, 3, 5, 7, the channels cde /, Fig. 1, 4- close at the top and bottom. —7 at., Of which c and d jointly run out into the inflow pipe g, FIGS. 1, 2, 3, e and / into the outflow pipe h, FIGS. 1, 2. If the present apparatus is used, e.g. B. in alcohol distilleries for measuring mash, the pipe socket g, Fig. 2 is connected to the pump that lifts the mash out of the Gährbottig; the other pipe socket k connects a pipe with the preheater of the distillation apparatus.

2. The control B. This has the purpose of the filling BEZW. The emptying of the measuring vessel can be regulated by means of the circular slide valve i (k) and the two end faces of the piston b are cleaned by the circular slide valve surfaces i (Jt). First of all, on each of the two circular slides i (k) there is a section of a circle, which on the one hand the opening through the one slide i, Fig. 5, 7 against the pipe socket g, the channel c and the Mefsgefafs a, on the other hand the opening through the other slide k , Fig. S, 7 against the pipe socket h, the channel / and the Mefsgefafs α forms, or the opening takes place in the reverse order, such that on the one hand the slide i the Mefsgefafs to the channel c and on the other hand the slide k after the channel d opens, so that when the measuring vessel α fills on one side by means of some pressure through the pipe socket g , the measuring vessel is emptied on the other side by the same pressure through the socket h as measured.

The piston /, Fig. 1, 3, 4, 5, 6, 7 of the cylinder ζ forms the essential part of this control. It is in direct contact with the mash to be measured and rises immediately after the filling of the measuring vessel by a certain pressure, the pump pressure. reverses and sinks back to the old position while the Mefs container is being emptied.

The piston / closes close to the wall of the cylinder ζ and has a hollow space which is intended for any weight loading, depending on the pressure exerted on this piston. One end of the rod m, FIG. 1, carrying the cross head η is screwed into the piston / and the other end is passed through the bearing g over the cross head η . Likewise, the two arms of the cross head η are guided by the brackets of Fig. 1, 2, 3 attached to the cylinder ζ . Each end of the arm of the cross head carries a rack 0, respectively. o ^l and a hook rod p hanging in a charnier, respectively. q, of which the rack 0 (0 ¹ J engages in the spur wheel t (u), Fig. 1, 2, 3, which is loosely seated on the shaft r (s) , and the hook rod / (q) in the also on the shaft r ( s) loosely seated hook washer ν (w). The spur gear / (u) contains a locking hook α (b), which a spring d (e), Fig. 3, laterally into the teeth of the locking wheel χ ( χ ^ι ) so that the spur gear t (u) is only coupled to the shaft r (s) when the locking hook α (b ) engages laterally in one of the two teeth of the locking wheel x. (x ^l) This only takes place when the piston rises, because when it descends, the spur gear rotates loosely on the shaft out of the teeth of the ratchet wheel. But the hook disc ν (w) also has a ratchet hook / (g) Fig. 2 the two radially standing teeth, which are distributed around the circumference of the ratchet wheel χ (χ ¹ ), only engage alternately when the spur gear t (u) rotates back, only then does the hook disk ν (w) stand with

the ratchet wheel χ (χ ¹ J coupled. In addition to the ratchet f (g) , each hook disc υ fw) has a lever arm h (i) with a weight k (I) attached to the end of the arm; the shaft r fs), on which, as mentioned, the locking wheel χ (χ) is stuck, is firmly connected to the circular slide i fk) , so that the circular slide i fk) only rotates when the locking wheel Wheel is given a spin. A steel screw m (n), Fig. 1, is screwed in the middle of each slide surface in such a way that both touch each other so that the piston always protrudes from the slide by 2 mm, as stated in the above calculation. The purpose of this is to prevent friction between the slide surfaces and the surface of the piston b when the slide i fk) is rotated.

The control acts on the measuring vessel in the following way:

As can be seen from the present drawing in FIG. 3, the piston / and the parts firmly connected to it (hook rod, toothed rack and weights) are in the lowest position. The channels c and /, Fig. 7 are open. The Mefsgefäfs has filled through channel c as a result of the pump pressure and the weight load in and around the piston /: the piston b is at rest on the right.

The piston / and the parts that are more firmly connected to it rise upwards through the liquid which is pumped up and which cannot escape through the measuring vessel (for piston b and circular slide valve i form the closure). The pull rod ο fo ¹ J rotates by means of the spur gear t fu ) connected to the locking wheel χ (χ ^χ ) the circular slide ifk) in the arrow direction indicated in Fig. 2 (to the right), and the hook rod p fq), the hook washer υ fw) in the opposite direction to the spur gear t fu) , but only loosely on the shaft r fs), up to the highest position in Fig. 1, whereby the circular slide k the channel d and the circular slide i the channel e in Fig 4 opens approx. ¹ ^ _{2 of} the whole circle section.

Once in the highest position, the screw ί fs ^l ) attached to the hook bar / (q) pushes the bar itself away from the hook disk ν fw) and releases the hook connection, the lifted weight k fl) hits down with the locking hook f fg) to one of the teeth of the ratchet wheel χ x ^x , this rotates together with the circular slide i fk) and opens the channels e fd). The measuring vessel now fills on the right and empties on the left, the piston b is pushed to the left as in Fig. 1 and has thus carried away the adhering liquid parts from the cylinder of the measuring vessel. Likewise, by rotating the slide i fk), the end face of the piston and that of the slide itself have been cleaned of the adhering liquid particles. In this way it is only possible to obtain an exact measure for thick, mushy, etc. liquids, as is especially the case with distillery mash.

Earlier the weight k fl) fell, the liquid forced itself into the measuring vessel by the pressure of the pump and the piston /, and since the weight in the hollow space of the piston is so heavily balanced that the piston I rather sinks before the whole If the filling of the Mefsgefäfses is done by the pump, this also sinks together with the rack and hook rod, again to the lowest position in Fig. 6. The piston b now rests on the left of Fig. 1, the piston / begins to rise, the slide opens again around the channels c and /, Fig. 5, as at the beginning of the explanation, which in turn fills the Mefsgefäfs through the channel c , pushes the piston b further to the right in the position of FIG. 7 and thereby the previous filling emptied through the channel f. The piston I has sunk down as in Fig. 6 and the game starts again. Thus, after every complete revolution of the slide i fk), the vessel has filled twice and emptied twice, and since one filling corresponds to 10 1, measurements were made in this way after every complete slide rotation.
. The counter C consists of the well-known wheels - translation in the ratio 1:10, provided with pointers and dials. The same is connected to the measuring vessel through one of these circular slides by means of a spur wheel x, Fig. 1, 3. In the accompanying drawing, the counter is attached to the left of the device. The spur wheel χ providing the transition has a ratio of 1: 5 to the larger wheel x ¹ , because, as mentioned above, 20 1 are measured after each slide turn, thus 100 1 for five revolutions. These five revolutions are marked on the first pointer of the counter by a one-time tour, on the second hand by a tenth tour, ie the hand is on the second dial on the number 1. So one hand controls the other and so the counter measures up to a million and even more, depending on the number of the activated wheels in the counter.

Claims (1)

Patent Claims: a) The cleaning of all the walls in the Mefs container, namely: τ. By reversing the circular slides i and k selected for this purpose on the end faces of the piston b and the slide surfaces themselves. 2, By the piston b sliding back and forth on the cylinder wall. b) The whole arrangement of the individual parts of the apparatus. 1 sheet of drawings.