RU2050931C1 - Device for automatic pouring over and filtering liquids - Google Patents

Abstract

FIELD: filtering. SUBSTANCE: upper lid of sealed tank of the device is provided with fastened suction pipe branch. Sliding sleeve with upper outer radial shoulder is put on the pipe branch. Lower part of the shoulder is processed for a valve plate interacting with a valve seat coaxial to the suction pipe branch. A ring gap is provided between seat opening and outer diameter of the sleeve. Suction valve has outer U-shaped flange with radial holes on the upper part of the pipe branch. EFFECT: high efficiency. 1 dwg

Description

 The invention relates to filtering and can be used for automatic transfusion and filtering various liquids in many industries, in particular in the manufacture of printed circuit boards.

 Closest to the proposed technical essence is the installation for filtering liquids, consisting of a filter, an intermediate tank, an ejector and a coupled float valve located in an additional tank.

 The intermediate capacity of the installation is connected through a pipeline to the lower filter chamber, and to the galvanic bath with a dyurite hose, which can easily be transferred to similar containers. The installation also contains control valves, vacuum gauges for measuring vacuum in the intermediate tank and in the filter filtrate chamber.

 The ejector is connected to a compressed air source by a pipeline and a ventilation system. The lower chamber is equipped with a float valve. The upper and lower chambers are connected by a filter partition. Installation works as follows.

 When compressed air passes through the ejector in the additional and intermediate containers and in the lower filter chamber, a vacuum is created by which liquid is pumped from the galvanic bath through the hose to the intermediate and additional containers, the two-way float valve rises and opens the lower valve through which the liquid is drained piping into the upper filter chamber.

 The liquid passes through the filter baffle and enters the lower chamber of the filter, from where it flows through the float valve into a galvanic bath.

 When the intermediate and additional tanks are filled with electrolyte, the float valve in the intermediate tank floats up and closes the upper valve, preventing the filtered fluid from entering through the ejector into the ventilation system. If there is no electrolyte in the tanks, then the float valve lowers, closes the bottom valve and stops the communication of these tanks with the atmosphere.

 The float valve installed in the lower filter chamber plays the same role. A float valve installed in its upper chamber prevents overflow of liquid into it.

 The disadvantages of this device include the complexity of the design, since it contains intermediate and additional tanks, interconnected with the filter by pipelines, and three float valves. Therefore, the device is distinguished by a high manufacturing cost and unreliability in operation.

 The aim of the invention is to simplify its design, lower manufacturing costs and increase reliability.

 The goal is achieved by the fact that the device contains a filter installed in the intake hose, which is connected to the sealed container through the first non-return valve, the drain pipe is connected to the sealed container through the second non-return valve, the float valve is made with loads and mounted on the stem with two stops in the sealed container , a suction nozzle is installed on the top cover of the sealed container, on which a sleeve with an upper radial collar, the lower part of which interacts with a top cover of the sealed container coaxially with the suction nozzle seat, between which an inner hole and the outer diameter of the sleeve an annular gap, a suction pipe at its upper part is formed with an outer U-shaped flange with radial holes.

 All this allows us to conclude about the novelty and significant differences of the proposed device for automatic transfusion and filtering liquids.

 The drawing shows a device.

 The device comprises a filter 1 installed in the intake hose 2, connected through a non-return valve 3 with a sealed container 4, a drain pipe 5 connected through a non-return valve 6 also with a sealed container, and a vacuum line 7. The latter is connected to a passive nozzle 8 of the ejector 9 with a diffuser 10, the active nozzle 11 of which is connected to the compressed air line 12. The device also contains pipelines 13, control valves 14, a float valve 15 with weights 16 mounted on a stem 17 with stops 18 and 19.

 A saddle 20 is made on the cover of the sealed container 4, between the inner hole of which and the outer diameter of the sleeve 21 there is an annular gap 22. The sleeve 21 is mounted on the suction pipe 23, the upper part of which has a U-shaped flange 24 with radial holes 25. The pipe 23 is attached to the cover sealed container 4 using a flange 26 and screws (not shown).

 In the container 27 is a liquid 28, which must be filtered and poured into the container 29. To obtain a vacuum, an ejector is used in the device.

 The device operates as follows.

 Before starting work, open the valve 14 in the compressed air line 12, which, passing through the active nozzle 11 of the ejector 9, creates a vacuum and, through its passive nozzle 8, draws air out of the vacuum line 7. Then open the valve 14 in the pipe 13, which connects the sealed container 4 with a vacuum line 7. When a certain vacuum is reached in a sealed container 4, the liquid 28 under atmospheric pressure from the tank 27, passing through the filter 1, the intake hose 2, the valve 14 and the non-return valve 3 will enter the sealed w container 4. In this case, the float 15 will rise and lift the upper position the stem 17, stop 18, which block the tube 23. Simultaneously rise and sleeve 21 and connect the hermetic vessel 4 through the annular gap 22 and openings 25 to the atmosphere. In this case, the rod will be kept in the upper position due to the pressure difference: vacuum in the pipe 23 and atmospheric air in the sealed container 4. In this case, the check valve 3 closes and the check valve 6 opens, the filtered liquid through it and the drain pipe 5 merge into the container 29 .

 After draining the liquid from the sealed container 4, the float valve 15 will lower due to the absence of the buoyancy force of the liquid, acting on the stop 19, will tear off the stem 17 from the pipe 23, since the weight of the float 15, its load 16 and rod 17 is greater than the differential pressure force with which they held up. In this case, the sealed container will again contact the vacuum line 7, and the cycle will be repeated.

 In the drawing, filter 1 is installed at the end of the intake hose, but as necessary, it can be installed anywhere else in this hose, and without this filter, the device is used for overflowing liquids.

 At the end of the operation, the taps 14 are closed. The choice of materials from which the device is made is determined by the properties of the liquids that need to be filtered or transfused. Such materials can be vinyl plastic, polyethylene, fluorine plastic, structural and stainless steels.

Claims (1)

 DEVICE FOR AUTOMATIC TRANSFUSION AND FILTRATION OF LIQUIDS, containing a filter, a sealed container with a suction hose and a drain pipe, an ejector, pipelines, control valves, a compressed air line, a float valve installed in a sealed container, characterized in that the filter is installed in the intake hose connected to a sealed container through the first non-return valve, a drain pipe connected to a sealed container through a second non-return valve, the float valve is made with loads and installed on a rod with two stops in a sealed container, a suction nozzle is installed on the upper cover of the sealed container, on which a freely sliding sleeve with an upper outer radial collar is placed coaxially with it, the lower part of which interacts with the seat made on the upper cover of the sealed container, coaxially with the suction pipe, the inner hole of which and the outer diameter of the sleeve is an annular gap, the suction pipe in the upper part is made with an external U-shaped flange with radial holes iai.

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