CZ148992A3 - Feeding unit of liquids, mounted on a float - Google Patents

Description

The hitherto used devices for treating drinking water with disinfectant solutions are based on dosing the disinfectant solution from the reservoir by dripping through a capillary. The disadvantage of such a device is that it does not allow the dosing of the disinfectant solution depending on the amount of water to be treated, which generally results in overdosing or underdosing of disinfection.

Also known are devices operating on the principle of pressurized water supplied to a system of vessels interconnected by capillaries. The disadvantage of these devices is the complexity and therefore the high demands on maintenance.

In the field of liquid dispensers there are also known devices with a dispensing device placed on the float, which monitors on the one hand the withdrawal from the surface with a logically less probable inflow of impurities into the device. the level above the inlet may be constant or adjustable to some extent, but both regardless of the instantaneous level in the dispenser reservoir. This then allows a finer adjustment of the flow rate through the regulating element, which mainly no longer changes as the level in the dispenser container rises or falls. Such a device is known, for example, from SU 440652, where the position of the dispenser itself is set in the float and thus the depth of the inlet openings to the dispenser is given, where the continuous flow is still tuned by a conical needle. In the lower end position, the needle with its cylindrical part can completely cover the inlet openings and thereby stop the flow.

Although the latter has a very wide control range, in the case of low flow rates the device is too sensitive to impurities, temperature and viscosity of the dosing liquid, in the case of larger flow rates the regulation is less accurate, and especially when fully closed

If the needle seal in the dispenser body is worn or, in principle, without seal, the flow is constant. Such a defect in some applications, for example for the aforementioned disinfectant dosing, can have very serious consequences for severe overdosing of disinfectant water at low disinfected water flow rates.

SUMMARY OF THE INVENTION

These drawbacks are overcome by the liquid dispensing unit on the float according to the present invention, wherein the dispensing unit body comprises an electromagnetic coil, the movable core of which is part of the working piston and at the same time a working space is arranged in the dispensing unit body. a working piston, and a transfer space, wherein the working and transfer space are separated by an inner wall provided with openings, the lower edges of which are above the liquid surface. Advantageously, the core of the electromagnetic coil is in the form of a guide rod on which a worktop is mounted at the bottom and a stop at the top above the electromagnetic coil. Advantageously, there may be at least a small clearance between the periphery of the worktop and the inner surface of the working space, particularly preferably in the range of 0.1 to 1 mm. It is furthermore advantageous if the transfer space has a sleeve on the peripheral wall adapted to receive a tube connecting the dispensing unit to the supplying location where the tube is flexible.

This achieves the creation of a dispensing device which is simple in construction and does not wear out the sealing surfaces at all, and even their failure is avoided in that the upper edge of the inner wall which lies above the surface prevents flow at rest. need. Furthermore, the device allows very accurate dosing, in addition to a very wide flow range. However, the advantages of the prior art closest devices, namely that the liquid to be metered is just below the surface, are fully maintained.

BRIEF DESCRIPTION OF THE DRAWINGS

The device according to the invention is further described in conjunction with the accompanying drawings, in which Fig. 1 is a schematic representation of the device in vertical axial section, Fig. 2 is a schematic embodiment in the rest state, and Fig. 3 is a schematic embodiment in working mode.

DETAILED DESCRIPTION OF THE INVENTION

The dosing unit on the float consists of the body 1 of the dosing unit, the electromagnetic coil 2, the float 3 and the working piston 4. In the body 1 of the dosing unit there is a working space 5 and a transfer space 6 separated from each other by an inner wall 8 provided with transfer holes 7 Above the upper horizontal wall of the body and of the dosing unit, there is an electromagnetic coil 2. The outer wall 9 of the transfer space 6 is provided with a sleeve 10 for the insertion of a pipe 11, which is flexible. In the working space 5, the working plate 12 of the working piston 4 is suspended on a guide rod 13 passing through the center of the electromagnetic coil 2. The guide rod thus forms the core of the electromagnetic coil 2, the guide rod 13 having a stop 14 at the top. It rests on the upper surface of the electromagnetic coil 2. Between the inner surface of the wall of the working space 5, which is actually the inner wall 8, and the periphery of the worktop 12, there is a relief slot 15 with a width of 0.1 mm. The body X of the dosing unit is inserted into a float 3 resting on the surface of the liquid 16 contained in the container 17. Thus, the entire dosing unit is placed in a container 17 filled with disinfectant solution. The unit floats on the surface and in the state of FIG. 1, the working piston 4 is slightly raised and the disinfectant solution is therefore also partly in the bypass space 6.

The described device operates as follows. In the idle mode, the working piston 4 is supported by its stop 14 on the upper surface of the electromagnetic coil 2, while the working plate 12 is at the lower edge of the working space 5. The liquid 16, which is a disinfectant solution, is passed through the bypass slot above the worktop 12, i.e. into the working space 5. The machine is brought into working mode by an electric pulse, the frequency and possibly duration of which depends disinfected water. This is done by means of a control unit (not shown) and a flow sensor of disinfected water. When dosing for other purposes, the control unit can change in its function and design, but always gives pulses with the necessary time

The working piston 4 is moved upward by the electromagnetic coil 2 by the action of the electromagnetic coil 2. The working plate 12 during this stroke displaces the liquid 16 present in the working space 5 through the through holes 7 into the through space 6. From there the liquid 16 flows freely through the sleeve 10 and the flexible tube 11 into the liquid 18 to be treated. After the electrical pulse has ended, the working piston returns freely to its rest position under its own weight. Space 5.

The dosing unit described herein or the like can also be used, for example, for laboratory sampling or wastewater sampling, or elsewhere where it is advantageous to position the sampling device at the surface and where the ability of the device to provide the highest reliability in sleep mode is assured. zero consumption. In the case of sampling, the sample liquid is, of course, drained into the prepared laboratory vessel, while during dosing it is introduced into a tank or pipeline for mixing, etc.

Claims (6)

A liquid dispensing unit mounted on a float, characterized in that the dispensing unit body (1) comprises an electromagnetic coil (2), the movable core of which is a part of the working piston (4) and a working space (1) 5), in which the worktop (12) of the working piston (4) is stored, and a transfer space (6), wherein the spaces (5,6) are separated by an inner wall (8), provided with discharge openings (7) whose lower edges they are above the liquid level (16). The metering unit according to claim 1, characterized in that the core of the electromagnetic coil (2) is in the form of a guide rod (13) on which a worktop (12) is mounted at the bottom and a stop (14) above. The metering unit according to claims 1 and 2, characterized in that at least a small clearance is provided between the periphery of the worktop (12) and the inner surface of the working space (5). Dispensing unit according to claim 3, characterized in that the clearance between the worktop (12) and the inner surface of the workspace (5) is in the range of 0.1 to 1 mm. Dosing unit according to Claims 1 to 4, characterized in that the discharge space (6) has an opening (10) on the peripheral wall (9) to which the pipe (11) is connected. The metering unit according to claims 1 to 5, characterized in that the pipe (11) connecting the metering unit to the supply point is flexible.