SU1703978A1 - Liquid dosage measuring device - Google Patents

Abstract

The invention relates to dispensing devices and allows for improved metering accuracy and speed. The fluid is pumped, for example, into the measuring chamber 1, the filling of which is controlled by the fixing unit of the upper level of the neck 3, made in the form of a cup 6 fixed in the collector tank 5 upside down coaxially to the throat, and is located above the neck 3, generates a signal for switching the closure element 14 when filling the cavity cavity 6 with liquid due to the fact that the throat area of the neck g 12 5 9 h 4 O CO che VI 00

Description

3 is larger than the area of the natural gas line with a lawyer and a glass communicated with the city capacity of 5 UL.IMJL; sensor 16 availability

LIQUID. IT HAPPENS TO .N-ANI W

doses due to the discharge of excess liquid through constipation between the glass and the neck, in which the liquid is set at the level of its upper end. 2 Il.

The invention relates to metrology, and to a metering device for standard continuous measuring and dispensing predetermined volumes of liquids, and can be used for high-precision calibration of tanks and dispensing of liquids, for example, doziropanil fuels, milk, juice and the like.

A dispenser in a single-sized measuring tank is known, which is a cylindrical Juice, to which, at various levels, depending on the range of measured values, dimensional measuring devices with visual scales of reference are attached. The dispenser has a drain unit, made in the form of a drain valve, a top level fixing unit containing a compensator, a tuning indicator, a throttle valve, and a nozzle, designed to eliminate level errors resulting from the impact of a falling jet on the liquid surface mirror in the exemplary measuring container.

A feature of this dispenser is 1, which is designed for manual reference measurement of liquids under laboratory conditions at a given temperature and cannot be used for continuous measurement and output of specified volumes (. TV fluid in automatic mode.

The disadvantage of the famous vl - s-1c dispenser is that the top-level fixing unit of the pdkost is complex in design and does not provide loading speed, although it ensures smooth filling to the prefixed level of the upper level.

11 the closest to the claimed dispenser according to its technical essence is a device for automatic measurement of volumetric flow-liquid (dispenser-flow meter) selected as a prototype, containing two separate measuring tanks, in the upper part of each of which there is a fixing unit of the upper level, including three-way . An adjusting valve and an upper nozzle, both of which fix the upper level of the liquid have an overflow node containing two regulating valves, upper nozzles, two reservoirs for accumulation zbytka fluid, overflow measuring container guide, dBZdatchika controlling overflow collector capacitances connected with level sensors, two air conduit to equalize the air pressure drops in the collecting containers for x and aqueducts

removal of excess liquid from the collector tanks to the measuring tank associated with them, as well as pipelines for draining the liquid from the measuring tanks.

In the lower part of the measuring tank, a lower level fixing unit is installed, which includes the lower branch pipe and a three-way adjusting valve. Two nodes of the lower level fixation are united by two nodes of filling-drain, each containing two

control valve and outlet piping.

In the dispenser described, the liquid flows into one measuring container through the inlet pipe of the loading-drain unit and through the lower branch pipe of the lower level fixing unit fills the measuring container. When the volumetric capacity overflows, the liquid passes through the upper nozzle of the upper level fixing unit and enters the corresponding collector capacity to a level limited by the action of the overflow monitoring sensor acting on the level indicator connected to the coding unit. After the level indicator triggers, the lower level fixing unit adjustment valve and the upper level fixing unit adjustment valve are activated at the same time, which fix the measured volume of liquid in

neutral position, and the excess liquid from the collector tank through the pipeline is discharged into another dimensional container, into which the liquid from the inlet pipeline passes through the time required for draining through the loading-unloading unit and its lower level fixing unit.

A disadvantage of the known device is the following. In the upper level fixation unit, inevitably,

gas and air bubbles that collect in the compartments of closed control valves that prevent the free discharge of gases from the filled measuring vessel. This affects the accuracy of the measured fluid volume.

In addition, when dispensing, it is necessary to retain the liquid at the inlet to the measuring tank with a liquid oil that is needed to completely drain the liquid from the collector tank, which reduces it (Dispenser Dispenser.

The purpose of the invention is improved dosing accuracy and speed.

This goal is achieved by that in the liquid dispenser containing measuring tanks, each of which is made with supply and slant pipelines and neck, equipped with an upper level fixing unit, according to the invention, a collector capacity is inserted, and the upper level fixing unit of each neck is made in the form of a glass with a sensor in it liquids, the cup being fixed in the collector tank upside down coaxially to the throat, the end of which is located in the cup below the sensor for the presence of liquid, and its flow area is larger than Azora between the neck glass and communicating with the collecting container on its bottom,

The execution of fixation units of the upper level with glasses provides with simple means a full and fast filling and a smooth refilling of measuring vessels with simultaneous release of gases from them. The presence of holes in the glasses ensures smooth drainage from their topped up to the upper fixed level of liquid. The presence of overflow monitoring sensors in the glasses associated with the shut-off elements makes it possible to automate the process of dispensing liquids and increase the versatility of the dispenser.

FIG. 1 shows the dispenser; in fig. 2 - the same, with the placement of the measuring tanks inside the collector tank.

The dispenser contains two measuring tanks 1 and 2 (Fig. 1) with elongated necks 3 and 4. Necks 3 and 4 are equipped with fixing units of the upper level of the liquid, which have one common collector capacity 5, into which necks 3 and 4 of the measuring tanks 1 come out. and 2. At the same time, the collector tank is coaxial with the necks of the volumetric tanks and placed upside down the glasses 6 and 7, into which the necks of the volumetric tanks partially enter with a gap. Glasses 6 and 7 can be made both cylindrical and conical. In the upper bottom part, the glasses are communicated with the collector tank 5 through the openings 8 and 9 for air to enter the glasses when the liquid is drained from them, intended for topping up the liquid in the throats of the measuring tanks. Glasses 8 and 9 may also be in the form of a hollow cylinder or ring open at the top and bottom.

The bottom of the collector tank 5 can be made funnel-shaped with an opening 10 to which the pipe 11 is connected. In addition, for the barrel air l from 5 of the collector tank 5 it can be connected in its upper part to the breathing valve t2.

Fundamentally, the dszator can be made with liquid bottoms from the bottom into measured 0 containers 1 and 2 and from above into the openings 3 and 4 of the measured containers.

When the liquid is supplied from the bottom of the measuring containers (Fig. -1), they are in the lower part

5 communicate with the supply pipe 13 for supplying fluid through the locking elements 14 and 15, for example, valves providing alternate supply of fluid to each of the measuring containers 1 and 2. Such

0 dispenser design provides accurate continuous dispensing of liquids.

To automate the dosing process, sensors 16 and 16 are placed in the cups above the necks of the containers, but below the holes.

5 17 the presence of fluid, and in the fluid supply lines, a temperature sensor 18 and shut-off elements 14 and 15 are installed, connected to the overflow control sensors. The sensors are connected to a control unit, such as a microprocessor (not shown), and allow for specific volume expansion at different temperatures when the metering container is poured and to turn off the flow to it.

5 liquids at receipt on the locking elements of the signal from the sensor control overflow. In order to carry out the sequential filling of the measuring containers and thereby to ensure the continuity of the dosage process, the dispenser can be equipped with control means, for example on the basis of a microprocessor, which are known.

In a number of cases, measuring tanks 1, 2 and 19 can be installed inside the collector tank (Fig. 2). This achieves the compactness of the dispenser, and such a design can be used, for example, to dispense juices, beer, kvass or similar liquids.

0B metrologically certified measuring tanks are used in any of the dispenser designs described, which, when used together and due to the design features described above

5 allows the reference dosing of liquids, which is alternately carried out in each of the containers, thereby achieving process continuity. This increases the speed of the dosing process itself. as when

filling one dimensional container is draining another container.

The use of a single collector tank for two dimensional tanks eliminates the use of complex control valves in the fixing unit of the upper liquid level. It also simplifies from the gas-air mixture from the filled measuring vessel.

The implementation of the upper level fixation unit with topping cups allows smooth and quick filling of liquid into the measuring containers, which also improves the accuracy and speed of the dispenser. The resulting excess liquid is drained into a single collector tank and easily disposed of, without complicating the design.

The dispenser works as follows.

To dispense a liquid, one of the measuring containers, for example 1, is metered with a liquid. The filling is carried out through the supply lines by means of the pump 20. At this time, the other measuring tank 2 remains unfilled. After filling the measuring container 1, the liquid enters the glass 6 located above the neck and triggers the sensor 16 for the presence of liquid, which signals the shutdown element 14 to shut off the supply of liquid to this container. Then, if necessary, measure the next volume of liquid. the element 15 of the other container 2 and filling it, while the first container 1 is emptied, yielding a measured volume of liquid. The process described above is repeated again, providing a continuous dosage of the liquid.

An important point to ensure the accuracy of dosing is the process of smooth and accurate topping up the liquid in the measuring containers. In the described construction, this is achieved with the help of glasses B and 7, into which the liquid enters from the necks 3 and 4 after filling the tanks 1 and 2 and smoothly flows through the gap between the cups 6 and 7 and the necks 3 and 4. It performed a smooth dolio-dimensional containers. For this, the sum of the areas of the passage section of the gap between the neck 3 or 4 of each measuring container and the glass 6 or 7, respectively, and the opening on the glass is smaller than the area of the passage section of the neck of this measuring container. The smoothness of the outflow of liquid from the glasses is also improved by the entry of air into the glasses through openings 8 and 9.

The use of the present invention improves the accuracy of measuring the volume of liquid to the reference in the automatic mode, the speed and compactness of the design compared to the prototype.

The speed of the dispenser is achieved by eliminating the time of filling the collector tank with liquid and draining it by gravity through a pipeline of complex configuration from the collector tank, as

0 took place in the known invention (prototype). Comparative model tests showed that the capacity of the dispenser is increased by 20%. In this case, it is also possible, with an accuracy of up to 0.05%, to carry out reference dosage, carried out by eliminating the formation of gas-air bubbles formed in control valves, and excluding pipelines.

0 of a complex configuration and thereby increase the smoothness and speed of the liquid filling to a fixed level in the measuring containers.

For comparison, the most accurate method for calibrating tanks using reference mergers in accordance with GOST 8.346-79 (Art. SEV 1972-79) was chosen as the base object. Horizontal steel tanks. Methods and means of verification. This method is rather laborious, since the loading is done manually with subsequent self-draining, requires intermediate measurements of the loading level and the corresponding volume

5 (for example, a 25 m capacity is calibrated within 5-6 days. Then the data is processed for another two days).

The advantages of the invention are that it is fully automated.

0 the whole process of calibration of tanks and using the invented dosing-flow meter you can get ready printed calibration tables (for example, calibration of 25 m3 reserver can be done in several hours over the entire practical temperature range).

The dispenser is in the final stage of manufacturing a prototype with the automatic control of the flow metering control process based on the microprocessor, with data output to the digital printing device.

Claims (1)

Invention Formula 5 A liquid dispenser containing measuring containers, each of which is made with supply and drain pipes and a neck, provided with an upper level fixing unit, characterized in that, in order to improve metering accuracy and speed, a collector capacity is introduced into it, each neck is made in the form of a glass with a sensor for the presence of liquid placed in it, the glass being fixed in the collector tank upside down coaxially to the throat, the end of which is located in the glass below the sensor of the presence of liquid, and the area of its flow area is larger than the area of the gap between the throat and the glass communicated with the collector tank above the sensor of the presence of liquid.