SU1194476A1 - Mixer - Google Patents

Abstract

A MIXER, comprising a housing with a flow chamber for the main fluid flow and an additional fluid injection channel connected to it, characterized in that, in order to improve the quality of the finished mixture by precision dosing of small amounts of additional fluid, it is equipped with a membrane metering device on the main fluid flow an additional fluid inlet channel, with a magnetic drive, made in the form of a shaft with parallel disks fixed on it, mounted in cross section of an eccentric flow chamber and cases and permanent magnets facing one another with poles of the same name, one of which is spring-loaded and connected to the dispenser membrane, and the other located on the surface of the upper disk facing the dispenser. 2. Mixer pop. 1, characterized in that the membrane metering device is provided with spring-loaded non-return valves located at the inlet and outlet of the metering chamber of the membrane metering device, and in the device case there is a channel connecting the cavity under the membrane to the atmosphere. 3. A mixer according to claim 1, characterized in that, in order to ensure the regulation of the dosage, the diaphragm metering device is provided with a filling tank installed at the outlet of the dosing chamber in front of the non-return valve, and the dosing chamber with an adjusting key. 4. The mixer according to claim 1, in order to improve mixing, it is equipped with a cyclone connected to the outlet of the flow chamber.

Description

The invention relates to mixer designs and can be used in chemical, food, petrochemical and other industries for mixing the main fluid flow with small amounts of metered liquid additives. The aim of the invention is to improve the quality of the finished mixture by precision dosing of small amounts of liquid additives into the main fluid flow, ensuring adjustment of the dosage, improving mixing. Figure 1 shows the mixer, a longitudinal section; figure 2 - section aa in Fig .; in FIG. 3, sections BB, in FIG. 2; in fig. 4 - section, bb In fig.Z; figure 5 - mixer with a cyclone, a general view; in fig. 6-8 stages of introducing the second liquid into the main stream of the first liquid; in fig. 9 - mixer with two dosing CALS for mixing three liquids, longitudinal section; figure 10 is the same, top view; figure 11 - mixer with multiple dosing chambers, top view; 12 is the same longitudinal section. The mixer consists of a horizontal body 1 with a flow chamber 2 for the main fluid flow and a channel 3 for the additional fluid connected to it, a container A for the additional liquid connected by a pipe 5 to the channel 3 for its introduction, flanges 6 connected to the ends of the body 1, a vertical shaft 7 installed in a flow-through chamber 2 eccentric to the axis of the housing 1, horizontal disks parallel to each other 8 mounted on the shaft 7 aligned permanently in the housing 1 of permanent magnets 9 and 10 facing each other with the poles, one of the CTDs; ryh 9 is fixed on the upper disc 8, and the second 10 — in the lower part of the dosing chamber 11, performed in the upper part of the housing 1, is eccentric to the shaft 7 and located between the inlet 12 and outlet 13 of the second input channel 3 (additional fluid, elastic membrane 14, placed in the dosing chamber 11 of the second magnet 10, the adjusting cap 15, movably installed in the upper part of the dosing chamber 6 I1 of the membrane metering device above the membrane 14, check valves 16 and 17, located in the channel 3 of the second fluid injection at the entrance and the outlet of the dosing chamber 11, the filling tank 18 with the nozzle 19 connected to the channel 3 for introducing the second liquid between its outlet 13 and one of the check valves 16, and the separation plate 20 made of a nonmagnetic material mounted on the inner wall of the housing 1 under the second magnet 10 and forming a gas cavity 21 connected by a gas channel 22 made in the housing 1 with the atmosphere. The mixer is equipped with a contactless magnetic sensor 23 mounted coaxially with the first: a magnet 9 and eccentric to the axis of the dosing chamber 11 on the inner wall of the housing 1, and a pulse recorder 24 connected to the sensor, as well as a cyclone 25 connected to the output of the housing 1. The mixer can also be used to mix several liquids under the condition that several dosing chambers with the corresponding reinforcing bond are filled in its casing, as shown in FIG. 9-12. The mixer works as follows. The main fluid flow is introduced into the housing I through one of the flanges 6 (for example, in FIG. 1, right-hand, i.e., the flow flows from right to left). The pressure passage chamber 2, the flow of the primary fluid, causes the rotation of the disks 8 fixed on the shaft 7 and rotating on it. Together with the upper disk 8, a permanent magnet 9 fixed on it rotates. A passage under the magnet 10 separated from the chamber 2 of the non-magnetic plate 20 (for example, stainless steel to eliminate the influence of liquids on the magnet 10 and the outer surface of the membrane 14), the magnet 9, facing the same pole towards magnet 10, causes the latter to rise, pushing away from it. When the magnet 10 is lifted together with it, the elastic membrane 14 rises in the metering chamber II of the membrane metering device, which can be made of elastic metal or synthetic material.

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(in case of insufficient elasticity, spring 26 is used to return) Membrane 14 pushes additional liquid from dosing chamber II, which has previously been fed into chamber 11 through valve 17 and channel 3 from container 4. When the membrane 14 is raised and the pressure in the chamber is created I1 this check valve 17 closes and opens valve 16 through which fluid from chamber I1 enters outlet 13 and further into chamber 2, in which it mixes with the main fluid flow.

The rotation of the magnet 9 provides periodic, cyclical input of additional fluid into the chamber 2 and its mixing with the main fluid flow. In order to avoid the formation of a vacuum in cavity 21 while raising membrane 14, a gas & channel 22 serves to connect cavity 21 to the atmosphere and thereby facilitating the operation of magnet 10 in atmospheric conditions.

Controlling the fill level of the dosing chamber 11 is carried out using a filling tank

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18, from which the second dose of 1m liquid is poured into the container 1I before starting the mixer. The dose adjustment of the second mixed liquid is carried out with the help of a movable cover 15, the displacement of which provides the required volume of dose of the additional liquid in chamber 11.

During the operation of the mixer, a continuous measurement of the flow rate of the finished mixture is carried out using a sensor 23 that perceives the magnetic field from the magnet 9 passing under it. As a result, the sensor

23 produces pulses that are recorded by the recorder 24. The whole mixing process can be automated by connecting the pulse recorder

24 through a special apparatus (not shown) to valves 16 and 17.

It is practically advantageous to make a multi-channel system with several dosing chambers 11, as shown in FIGS. 9-12, which provides a mixture of several liquids.

Claims (4)

A MIXER containing a housing with a flow chamber for the main fluid flow and an additional fluid inlet channel connected to it, characterized in that, in order to improve the quality of the finished mixture by precision dosing of small quantities of additional fluid into the main fluid flow, it is equipped with a membrane dispenser installed on the input channel of the additional fluid, with a magnetic drive, made in the form of a shaft with parallel disks mounted on it, mounted in a cross section of the flow chamber in an eccentric axis housing; and permanent magnets facing one another with the same poles, one of which is spring loaded and connected to the metering membrane, and the other is located on the surface of the upper disk facing the metering unit. 2. The mixer according to claim 1, characterized in that the membrane dispenser is equipped with spring-loaded check valves located at the inlet and outlet of the metering chamber of the membrane dispenser, and a channel is made in the device body connecting the cavity under the membrane with the atmosphere. _β 3. The mixer according to claim 1, about t l and - Ochischaya that, in order to ensure dosage regulation, the membrane dispenser is equipped with a filling tank installed at the outlet of the metering chamber in front of the check valve, and the metering chamber with an adjustment cover. 4. Mixer according to claim 1, m l of ichayuschiysya in that, in order to improve the mixing, it is provided with _ι cyclone connected to the outlet flow chamber. SLL.1194476