SU32177A1 - Fluid dispenser - Google Patents

Description

Apparatuses for metering liquids are known by means of two supply tanks connected by a rotary distributor controlled by an electromagnetic device. In the proposed apparatus, in order to carry out a periodic rotation of the spool when the contacts are closed, the cores of the solenoids are made in the form of two arcs and are fixed on the arms joined to the spool.

In FIG. I depicts a front view of the apparatus, with a partial section; FIG. 2 is a section along line AB in FIG. I; FIG. 3-slit on the switch.

Two vessels of rectangular section S and 5 (Figs. 1 and 2) made from sheet iron are connected together, with a common partition in the middle. The bottom of the vessels has a slope to the outlet, facilitating the descent of the liquid to the end. A distribution box q is placed at the bottom of the device, at the junction of both vessels, simultaneously serving both vessels. The box is cast from cast iron and has the corresponding flanges, to which the vessel walls are welded. Cylinders 392.

The caddy part of the junction box q accommodates a distribution valve, which, on the one hand, separates the fluid inlet channel from the outlet channel, and, on the other hand, closes the openings O, which serve to enter and exit the liquid from the vessel. The spool g, which has the form of two connected segments rotating along with the roller (along the end of the box) along the entire length of the box, turns into a full and slightly cut disc, which ensures complete separation of incoming and outgoing liquids. Distributive box (goes along the long side of the vessel rectangle (approximately for large gauges about 1 m long). Accordingly, connecting windows have the form of long narrow slits, which ensures their large throughput at a relatively small (30 °) angle of rotation of the spool for shut off. The inlet is at the back of the device and goes into a rectangular channel of the same cross section that forms the upper part of the box. The same lower rectangular channel that serves to exit the liquid goes into the pipe clean section, allowing liquid to be poured out at the required rate.

In the / - / position (Fig. 2), the goldfish stands in such a way that the liquid flows into the vessel 5 and pours out of the vessel 5. In the // - // position, when turning the spool by 30 °, the opposite direction occurs. Vessel sizes are calculated so that the alternate filling and emptying of vessels occurs once a minute. To create the required density, the spool g with a roller /, sealed in the gland, is provided with oil grooves and is drained slightly onto the cone, which allows pressing it to a certain extent.

The sliding valve of the valve from the position / - / to the position of the // - // (turning 30 °), and back is carried out by a system of electromagnets with mercury switches in the tubes b and temperature equalizer g /. Their action is as follows. Iron-arched cores d, which are included in solenoids of electromagnets i of sufficient power, are supplied with a roller in conjugate and spokes, through a rheostat from a common direct current network. On the sides of the junction box q there are poured grooves with holes at the top, where a glass tube m with a diameter of about 12 mm is open at the top. This tube (fig. 3) at the end passes into the siphon knee and then into the vertical tube b with a diameter of about 5 mm. Through the rubber ring p and the plug n on the thread, the tube is sealed accordingly.

The tube is filled to half the cross section with mercury, so that its mirror is at the level of the middle section of the conical bottom of the vessels. Through holes in the groove, the mercury in the tube communicates with a column of fluid in the vessels. Tube dimensions eliminate capillary events. When a vessel is filled with liquid, then, depending on its specific gravity, mercury, according to the law of communicating vessels, rises in a vertical tube b to a certain height; at the same time, the level in the horizontal part is lowered only by 0.8 liter, and that, obviously, does not affect the counting. Lifted

through a vertical tube, mercury through two needles U and / produces a short circuit of the electric current that passes through the electromagnet f and engages the core d until it stops against the core e. At the same time, the spool g associated with the core d rotates 30 °.

With thick liquids, in order to avoid blockages with sugar or the like, the pipes, which are made wider and shorter, give the appearance of a brush, and in the vessel in question the inlet is closed and the outlet opens; in the second vessel, vice versa. The first vessel begins to be emptied, and the second one is filled. When the second vessel is filled to a certain height, the mercury in the corresponding switch of tube B rises to the closing needle, the current is turned on, the electromagnet draws in an arc and turns the gold switch to its original position, etc.

The force of the electromagnet must be such that it only overcomes the force of friction when turning the balanced spool of the city. Once turned, the goldman remains in the same position and when the current is opened, it is obvious that immediately after the start of the pouring out of the liquid; the next turning occurs at the new current closure, etc. Since the needle is at a certain height, the vessels are filled until the mercury in the tube b reaches a certain specified height.

Thus, the liquid in vessels has a variable height, depending on its specific gravity, but always corresponding to a certain pressure at the bottom of the vessel, equal to the pressure of a given mercury column. By knowing the area of the vessel and the pressure on 1 m bottom, it is possible to calculate the weight of the fluid in each vessel or determine it by means of a test pressure. The cores d are connected by a lever with an ordinary counter, which shows the number of double vibrations. According to a certain weight and meter reading, it is possible to determine the weight of the entire sheet that passes through the vessels at a given time.

To exclude temperature effects, an additional tube (“deaf”) is placed next to the main tube b.

It is mercury of the same height as the contact and has the same temperature. It contains an ebonite float associated with the needle fz. As the temperature rises, mercury in the equalizer y rises and at the same time raises the float with the needle c. As a consequence, in tube 6, mercury before contact with the needle must rise to a greater height, namely, to a height corresponding to lowering its specific weight from heating with constant pressure to the bottom, which is achieved by equal switch and equalizer heights. Thus, thanks to the equalizer, the pressure of the mercury column remains unchanged, regardless of the temperature, and therefore the weight of the fluid filling the vessel until the moment of contact remains unchanged. In other words, the instrument reading gives the same weight values, independent of the state of a particular fluid with respect to its specific weight, temperature, and so on.

The subject matter of the invention.

Claims (2)

1. A device for dispensing a liquid using two supply tanks interconnected by a rotary zolotnik distributor controlled by an electromagnetic device, differing in the fact that cores d solenoids made in the form of two arcs are mounted on articulated arms with a spool g to perform a periodic hull the spool when the contacts are closed by a mercury column enclosed in tubes b communicating with the supply tanks. 2. In the apparatus of claim 1, use deaf additional tubes of mercury, on the surface of which floats are placed, which serve to move the contacts of the main tube b from each other with increasing temperature.