FI97217C - A dosage - Google Patents

Description

97217

A dosage

Doseringsanordning The invention relates to a dispensing device for dispensing liquids, comprising a tank, an inflow connection for directing a liquid flow into the tank, an outflow connection for removing the amount of liquid flowing into the tank from the tank and a propellant supply connection for supplying a pressurized propellant flow to the tank.

10 Pumping liquids often involves many difficulties. The fluid to be pumped may contain varying amounts of solids. Particularly troublesome are solvent-containing liquids which, when pumped, may dissolve or at least generally soften. Furthermore, the valves used in the pump unit are corroded. Small or variable volume volumes also make it difficult to dispense the fluids being pumped. Likewise, the boiling or evaporation of the liquids to be pumped 15 complicates the pumping operation.

Due to the difficult pumping conditions described above, there are often cases where conventional centrifugal pumps are out of the question at all. Likewise, piston pumps are not always usable because they may have wear or vacuum difficulties, causing the piston pump to suck up empty. In fact, very small volumes of pumped liquid are almost impossible to implement with centrifugal pumps, especially if relatively high head requirements are required.

The solids in the pumped liquid are very harmful to the piston pump-25 trees. Such are, for example, liquids containing sand and / or gravel, which sometimes make the use of a piston pump downright impossible.

The functions of the valves that close in diaphragm pumps become uncertain if there is a lot of harmful solids in the liquid to be pumped. In addition, the materials of the valves in the diaphragm pumps 30 may dissolve in some of the substances in the liquid to be pumped. As a result, the use of diaphragm pumps is also limited to the liquids that are suitable for them.

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The chemical industry is experiencing the difficulties described above with regard to pumped liquids, as a result of which conventional pumps cannot function satisfactorily. Chemical processes are often hot, as a result of which particles that can withstand normal conditions can no longer withstand hot conditions. The quantities of liquids S to be pumped or the quality of the liquids to be pumped also limit the use of conventional pumping solutions in the chemical industry.

The object of the invention is to provide a dispensing device which is suitable for very demanding conditions in the most reliable way possible. It is a more detailed object of the invention to provide a dispensing device with a simple structure and as reliable a function as possible.

The objects of the invention are achieved by a dispensing device, characterized in that a second tubular member 15 of larger diameter is arranged around the inflow connection, whereby an annular space is formed between the inflow connection and the tubular member. is adapted to move in · against the flow connection tightly under the influence of the propellant gas flow and away from the inflow connection when the effect of the propellant gas flow ceases.

20

The operation of the dispensing device according to the invention is based on the flow of the pumped liquid with any impurities therein under its own hydrostatic pressure to the dispenser, from which a corresponding volume of gas exits through the opening (s) in the barrier membrane. Thereafter, in the dosing device 25 according to the invention, the pumping takes place with a pressurized gas so that its inflow into the liquid-filled dosing space causes the liquid inflow channel to close. At the same time, due to the pressure of the inflowing gas flow, the sealing membrane of the upper lid of the dispenser device presses against the upper lid, closing the holes in the sealing membrane, creating a closed pressure space in the dispenser, leading to the flow of liquid

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The invention will be explained in detail with reference to the basic solution of the invention shown in the figure of the accompanying drawing, to which, however, the invention is not intended to be exclusively limited.

The drawing shows a preferred embodiment of a dispensing device according to the invention in a schematic, partially sectioned side view.

In the drawing figure, the dispensing device according to the invention is generally indicated by reference numeral 10. The dispensing device 10 comprises a tank 11, an inflow pipe 19, 10 a liquid outflow pipe 14 and a compressed air supply duct 16. The liquid inflow is indicated by

The bottom of the container 11 preferably, but not necessarily, has a recess 15 which allows the container 11 to be emptied in a single dose up to the bottom of the container 11. The upper part of the container 11 has an opening covered by a lid 17. The lid 17 is associated with an upwardly directed tubular part 12 to which a pumped liquid outlet channel 14 is connected above the lid 17. In this embodiment, the upper end of the tubular part 12 has a sleeve 13 or a flange connection.

20

The inflow pipe 19 is surrounded by a second pipe 20 and both pipes 19 and 20 extend close to the bottom of the tank 11. In this embodiment, the tube 20 is detached and the tube 20 is attached at its upper end to an opening in the seal 18 associated with the cover 17, e.g. by a flange attachment. An annular space is formed between the tubes 19 and 20 for the outflow of the liquid in the tank 11. The recess 15 has a seal 22 provided with a washer 23 below it. The plate 23 is provided with a guide pin 24, * whereby the plate 23 moves and is guided by a pressurized propellant, e.g. compressed air, in the supply duct 16. The propellant supply flow C is thus adapted to operate with a guide pin 24. that the supply flow C of the pressurized driving air or its exhaust 30 causes the guide pin 24 to move in an up-down direction, i.e. the plate 23 4 97217 for its seals 22 closes or opens the inflow channel 19 and thus regulates the inflow A of the pumped liquid to the tank 11.

The inlet pipe 19 is arranged so that there is a suitable space between the seal 22 and the lower end of the inflow pipe 19 5 so that the liquid flow A can flow freely and desirably into the tank 11 during the filling step. The second tube 20 is slightly shorter or as long as the inflow tube 19. The tube 20 may be provided with tooth crimping or the like to allow fluid to flow into the annular space 21 between the tubes 19 and 20 and through it to the outflow tube 14. 23 are in their uppermost position, i.e. pressed tightly against the mouth of the inflow pipe 19.

When the propellant gas flow C is closed, the liquid flow A takes place in the tank 11 along the inflow pipe 19 with the seal 22 and the plate 23 with its guide pins 24 in the lower position. In this case, the gas in the tank 11 has to leave the tank 11. For this purpose, the seal 18 has a hole or holes 25 outside the expanded flange part of the second pipe 20 in the opening at the upper end of the tank 11. In the emptying stage, the seal 18 rises immediately tightly against the cover 17 due to the gas flow C. The seal 18 also rises due to the fact that the plate 23 and the seal 22 on it have to rise rapidly due to the gas flow C, pushing further a second pipe 20, the upper end of which is supported by the seal 18. In this case, the hole or holes 25 in the seal 18 <· are closed by pressure against the cover 17 and the gas flow C flowing into the tank 11 immediately begins to pressure the tank 11. As a result, the liquid flowing into the tank 11 immediately and strongly discharges Only when all the liquid has flowed from the tank 11 through the intermediate space 21 can the pressurized gas flowing into the tank 11 escape through the same space. When the gas flow C ceases, the poppet valve 23 with its seals 22 can descend under the control pin 24 in the flow channel 16, whereby the orifice of the inflow pipe 19 is released, the pipe 20 descends and the hole or holes 25 in the seal 18 open. In this case, the liquid can again immediately flow as a flow A along the pipe 19 and fill the tank 11. The air / gas emanating from the tank 5 97217 11 can flow out through the opening or openings 25 in the seal 18 into the outflow channel 14.

The dosing pump according to the invention, i.e. the dosing device 10, is very reliable.

5 If a sedimented accumulation forms at the bottom of the tank 11, during the gas flow C such sedimented accumulation immediately separates and mixes with the liquid in the tank 11 and flows with the liquid through the annular space 21 between the pipes 19 and 20 into the outflow channel 14. If in pumping operation the outflow channel 14 If the tank 11 or even the tank 11 were clogged, such clogging 10 can be easily removed, e.g. 10. If necessary, such a cleaning operation can be automatically tracked, e.g. as a remote control.

The dispensing device according to the invention is reliable and the dispensing device, i.e. the single-dose pump, can pump different amounts and solutions / liquids as required, even at different temperatures and pressures. The seal 22 can be made of special materials or the seal 22 can even be omitted altogether, whereby the poppet valve or the poppet plate 23 can be of a soft material compared to the material of the pipe 19, i.e. the material of the mouth end of the pipe 19. The pressurized gas flow C can be selected and controlled according to the current need, in which case the pumping frequency can be dispensed, etc. The gas flow C can be selected or controlled so that the tank 11 and the outflow channel 14 are just emptied or otherwise required. With the dosing device according to the invention, the inflow A can be * monitored so that not the slightest gas flow from the tank 11 is directed against the inflow A, which is often necessary especially in cases where the inflow A has slowly settling fines or sedimentation sludge is desired. 11.

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The solution according to the invention is in no way critical for the exact placement of the components shown in the figure of the drawing. The hole 25 can be in the tube 20, for example, just below the lid 17. In this case, the amount of gas leaving through the hole 25 must be less than the amount of gas flowing past the guide pin 24 in the flow channel 16 in order to obtain sufficient pressure in the tank 11 during the emptying phase. Such a solution can cause a risk of clogging of the dispensing device and, in addition, too slow filling of the tank 11 during the inflow A. because the discharge of the gas displaced from the tank 11 into the outflow channel 14 can take place too slowly.

The hole 25 can also be discharged, e.g. through the lid 17, and the closing of the hole 25 can be monitored, e.g. by a float, when the liquid level in the tank 11 rises up to the lid 17.

The pipe 20 does not necessarily have to be concentric with the inflow pipe 19. Of course, it is clear that even then the outflow channel 14 is also an extension of the pipe 20 15.

Only one preferred embodiment of the invention has been described above, and it will be clear to a person skilled in the art that numerous modifications can be made to it within the scope of the inventive idea set out in the appended claims.

20 • «! L» lii! i i = 1.

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Claims (11)

A dispensing device (10) for dispensing liquids, comprising a tank (11), an inflow connection (19) for directing a liquid flow (A) to the tank (11), an outflow connection 5 (14) for removing the amount of liquid flowing into the tank (11) from the tank (11) and a driving gas supply connection (16) for directing a pressurized propellant gas flow (C) into the tank (11), characterized in that a second tubular member (20) of larger diameter is arranged around the inflow connection (19), whereby an annular space is formed between the inflow connection (19) and the tubular member (20). 21) for conveying liquid from the tank (11) along said annular space (21) to the outflow connection (14), and that at the bottom of the tank (11) there are sealing means (22, 23, 24) adapted to move tightly against the inflow connection (19) C) away from the effect and the inflow connection (19) after the effect of the driving gas flow (C) has ceased. Dispensing device according to claim 1, characterized in that the inlet connection (19) is arranged to terminate at a distance from the bottom of the container (11) so that there is space between the inlet connection (19) and the sealing members (22,23,24) for liquid flow (A). to flow freely into the tank (11) during the filling phase. Dispensing device according to Claim 1 or 2, characterized in that the second tubular element (20) is slightly shorter or equal to the inflow connection (19). Dispensing device according to one of Claims 1 to 3, characterized in that the container (11) is provided with a lid (17) at its upper end, and that a sealing element (18) is connected to the lid (17). Dispensing device according to Claim 4, characterized in that the sealing element (18) is provided with a hole or thigh (25). 30 g 97217 Dispensing device according to one of Claims 1 to 5, characterized in that the second tubular element (20) is adapted to move in an up-down direction. Dispensing device according to one of Claims 4 to 6, characterized in that the second tubular element (20) is fastened to the sealing element (18). 7 97217 Dispensing device according to one of Claims 1 to 7, characterized in that the sealing elements (22, 23, 24) comprise a seal (22), a disc plate (23) and a movably adapted guide pin (24) connected to the plate plate (23). . 10 Dispensing device according to one of Claims 1 to 8, characterized in that the bottom of the container (11) has a recess (15). Dispensing device according to one of Claims 1 to 9, characterized in that an outwardly directed tubular part (12) is connected to the lid (17) covering the opening in the upper part of the container (11). Dispensing device according to Claim 10, characterized in that a sleeve or flange connection (13) is arranged at the upper end of the tubular part (12). 20 s * 4 Il I Mlk »iti lii; ·· 'i 97217 9