NL1040412C2 - LIQUID DOSING DEVICE DRIVEN BY THE PRESSURE OF THE WATER LINE. - Google Patents

Abstract

Dosing device for adding a second liquid to a primary liquid in a specific proportion, consisting of a reservoir (1) in which a float (7) has been applied in such a way that it will only close the liquid supply (2) and open the liquid drainage (3) when the desired amount of primary liquid is stored in the reservoir (1) and in which the second liquid is measured by a pump, controlled by pressure changes in the supply line, and then added to the primary liquid.

Description

Liquid dosing device driven by the pressure of the water pipe.

Various methods are known for adding a second liquid, for example consisting of medicines or disinfectants, dosed automatically to a first liquid. Often a dosing device is used for this purpose, which is connected to a supply line or a reservoir with a first liquid.

Some dosing devices work with electricity and electronics. An amount of first liquid is measured as precisely as possible and then the desired amount of second liquid is added by means of programmed electronics.

Devices are also known that function without using electricity. Such an apparatus is known from patent application EP0885357.

Both types of devices are expensive, complex and also have the disadvantage that the second liquid, sometimes an aggressive medicine or disinfectant, mixes with the first liquid in the device itself in such a way that the mixture comes into contact with vulnerable parts of the device. dosing pump which sometimes causes damage to the device.

The object of the invention is to develop a dosing device that does not have these disadvantages. This object is achieved according to the invention by providing the device, which consists of a reservoir connected to the water pipe, with a device which ensures that the reservoir is filled with a measured amount of first liquid. By draining and refilling this reservoir, a certain amount of liquid is used every time that is used for application. The apparatus is also provided with a device that can measure a certain amount of the second liquid and add it to the measured amount of first liquid described above, so that the mixture can be used.

A method of measuring a certain amount of first liquid is to place a clock in the reservoir which does not rest on the bottom of this reservoir but remains free of it. There is a float in the clock. The supply of the water, which takes place on the inside of the clock, is shut off by the float as soon as the liquid in the reservoir has reached the desired level. As soon as the reservoir starts to empty again, the liquid level will drop outside the clock and not below the clock. This is because no air is allowed under the clock. However, as soon as the water level on the outside of the clock falls below the bottom of the clock, air is admitted there and the clock will empty and the float will open the liquid supply again, after which the process will repeat itself. In order to keep the amount of water that must be added in each case as constant as possible, it is necessary that the supply line of the liquid, which in the exemplary embodiment consists of water and is under the normal water line pressure, must be able to fill the reservoir much faster than that the reservoir fills itself. can empty.

Another method of measuring a certain amount of first liquid is to place a tube around the liquid supply at the top of the reservoir in which a float can move up and down. By choosing the space between the float and the inner wall of the tube that surrounds the liquid supply, a large downward pressure will be exerted on the float as soon as the liquid supply is opened. This is because the fluid encounters resistance as it passes through the narrow space between the narrow elongated portion of the float and the inner wall of the tube around the fluid supply.

However, as soon as the level of the liquid in the reservoir rises, the upward pressure becomes greater than the said downward pressure, the float will close the relatively small opening of the supply and little upward pressure is then required to close it to hold. As soon as the reservoir starts to empty again, the liquid level will have to drop far before the float opens the water supply again and due to the now greater downward pressure the liquid in the reservoir will have to rise to a much higher level before the float closes the supply again . Here too it holds that the supply must be able to fill the reservoir much faster than it can empty itself.

The dosing of the second liquid to be added can take place as follows.

When the reservoir is filled, the pressure in the supply line decreases, so that a pressure difference in the supply line is created each time. This can be used for dosing the agent.

In order to locally increase this pressure difference in the supply line during filling and non-filling of the reservoir, a narrowed passage is placed in the supply line just before the opening in the reservoir that is smaller than the opening to the reservoir. You can also choose the design so that a water jet air pump forms there.

By making a branch at this location to a spring-driven pump, it is possible to add an accurately determined amount of agent to the reservoir with each filling of the reservoir.

In order to prevent partial emptying of the reservoir of the device, as described in the first variant with the clock, during filling and thus to more accurately measure the determined amount of first liquid, the reservoir is provided with a valve outside and inside the clock. These valves are controlled by the pressure differences in the above-described branch, so that during filling, when a low pressure or underpressure is created, the valve is closed outside the clock and the valve is opened within the clock. In this way, air can escape and there is no overpressure within the clock. In this way no liquid can flow out of the reservoir during filling, so that the liquid to be measured is accurately determined. As soon as the liquid supply to the reservoir is closed, the overpressure in the branch will close the valve outside the clock and open the valve within the clock so that liquid can flow out of the reservoir and no air is allowed under the clock.

In order to prevent partial draining of the reservoir of the device as described in the second variant with the tube during filling and thus to more accurately measure the determined amount of first liquid, the reservoir is provided with a valve in the outlet opening of the reservoir, which is controlled by the pressure differences in the above-described branch, so that during filling, when a low pressure or underpressure is created, this valve is closed. In this way no liquid will flow out of the reservoir during filling, so that the liquid to be measured is accurately determined each time. As soon as the liquid supply to the reservoir is closed, the excess pressure in the branch will open the valve, so that the measured amount of liquid can flow out of the reservoir.

The invention will be explained in more detail below with reference to a model of an embodiment of the device schematically shown in figures.

FIG. 1

Shows a cross-section of the device according to the invention. Reservoir (1) is provided with a liquid inlet (2) in a liquid outlet (3). This reservoir can measure and contain a certain amount of first liquid. To that end, there is a bell (4) in the reservoir (1) which remains free of the bottom (5) of this reservoir. The liquid outflow opening (6) comes out in the clock. This is connected to the liquid supply (2). There is float in the clock (7), which will close the outflow opening (6) as soon as the reservoir (1) is filled with the desired amount of the first liquid. The non-return valve (8) placed in the clock allows the air to escape when filling the reservoir to prevent overpressure in the clock (4). If the reservoir starts to empty, the level of the liquid outside the clock will first fall because underpressure forms inside the clock. If the level falls below the open bottom (9) of the clock (4), air will only be supplied and the clock will empty. This will open the outflow opening (6), new liquid will flow into the reservoir and the process will repeat itself.

FIG. 2

Shows a variant of the device according to the invention as described in Figs. 1 Around the liquid outlet opening (10) in the reservoir (11) there is a tube (12) in which float (13) can move. The space between the float (13) and the inside of the tube (12) is chosen to be so small that when the outflow opening (10) opens, the inflowing liquid encounters resistance as it passes through the narrow space. As a result, a great downward pressure is exerted on the float (13). If, as a result of the rise in the liquid level around the float, the upward pressure becomes greater than the downward pressure, the float (13) will close the small outflow opening (10).

Little upward pressure is needed to keep it closed. Thus, the float (13) will only open the outflow opening (10) when the liquid level has fallen sharply and a measured amount of the first liquid can flow out of the reservoir before the liquid outflow opening (10) is opened again, after which the process will repeat itself. .

FIG. 3

Shows the device according to the invention for measuring and adding the second liquid to the first liquid. This metering takes place in that a branch (15) is arranged in the liquid supply line (14). At the location of the branch, the supply line is designed in such a way that in the branch (15), when the liquid is opened, outflow opening (18) develops underpressure during the filling of the reservoir (17). On the other hand, when the liquid outflow opening (18) to the reservoir (17) is closed, the full pressure of the supply line (14) remains in the branch (15). This change of pressure is used to control a piston, diaphragm or other type of pump (19). In this way the amount of second liquid can be sucked up from storage tank (21) and accurately measured, added via hose (20) to the first liquid in the reservoir (17).

FIG

Shows a device according to the invention which serves to prevent partial emptying of the reservoir (1) of the device, as described in Fig. 1, during filling. In this way the desired amount of first liquid is measured more accurately. To this end, the reservoir (22) is provided with a valve (23) on the bottom and a valve (26) on the top inside the clock (24). These valves are controlled by the pressure differences in the branch (25) of the supply line. When filling the reservoir, a low pressure or underpressure will arise, whereby valve (23) is closed and the valve (26) is opened. Air can escape via valve (26) and there is no excess pressure within the clock (24), and because valve (23) is closed, no liquid can flow out of the reservoir (22) during filling. In this way the liquid to be measured is accurately determined. As soon as the liquid outflow opening (27) is closed to the reservoir, the excess pressure in the branch (25) will open the valve (23) and close the valve (26) so that liquid can flow out of the reservoir and no air is admitted under the clock.

FIG. 5

Shows a device according to the invention which serves to prevent partial emptying of the reservoir (11) of the device as described in Fig. 2 during filling. In this way the desired amount of first liquid is measured more accurately. To this end, the reservoir (28) is provided with a valve (29). This valve is controlled by the pressure differences in the branch (31). During filling, when a low pressure or underpressure is created, the valve (29) will be closed, so that no liquid can flow out of the reservoir during filling. In this way the respective liquid to be measured is accurately determined. As soon as the liquid supply (32) to the reservoir (28) is closed, the excess pressure in the branch (31) will open the valve (29), so that the measured amount of liquid can flow out of the reservoir (28).

Claims (5)

A dosing device that adds a second liquid in a certain ratio to a first liquid by first measuring a certain amount of first liquid and adding to it a certain measured amount of second liquid, the device consisting of a reservoir (1) with a liquid supply (2) and a liquid discharge (3) and the reservoir (1) can measure and contain a certain amount of the first liquid, characterized in that in the reservoir (1) there is a clock (4) which remains free of the bottom (5) of this reservoir and into which bell (4) the liquid outflow opening (6) comes out, wherein there is a float (7) in the clock that will close the liquid outflow opening (6) as soon as the desired amount of the first liquid in the reservoir (1) has flowed in while a non-return valve (8) placed in the clock allows air to escape so that no overpressure is created within the clock, whereby if the reservoir starts to empty liquid outside the clock will drop because underpressure will form inside the clock and only when the level of the liquid falls below the open bottom (9) of the clock, will air be supplied and the clock (4) will empty, after which the float (7) ) the liquid outlet opening (6) will open again, after which the process will repeat itself. A variant of the device according to claim 1, characterized in that a tube (12) is placed around the liquid outflow opening (10) in the reservoir (11) in which the float (13) can move, the space between the float (13) ) and the inner wall of the tube (12) is selected to be so small that when the liquid outflow opening (10) is opened, the liquid encounters resistance as it passes through this narrow space thereby exerting a great downward pressure on the float (13) and if, as the level of the liquid around the float (13) rises, the upward pressure becomes greater than the downward pressure, the float (13) will close the relatively small liquid outlet (10) and because it requires little upward pressure is to keep it closed, the float will only open the outflow opening when the liquid level has fallen sharply so that a measured amount of first liquid can always flow out of the reservoir before the flow The dust outlet opening is opened again, after which the process will repeat itself. A device according to claims 1 and 2, characterized in that the second liquid is measured and added in that a branch (15) is arranged in the liquid supply line (14), the supply line being shaped at that location by narrowing (16) such that branch (15) during the filling of the reservoir (17) underpressure arises, while, when the liquid outflow opening (18) to the reservoir (17) is closed, the full pressure of the supply line prevails in the branch and using this change of pressure is used to control a piston, diaphragm or other type of pump (19), whereby the amount of second liquid can be accurately sucked up and measured from storage tank (21) and can flow into the reservoir (17) via hose (20) and thus be added to the first liquid. A device according to 1 and 3, characterized in that, in order to prevent partial emptying of the reservoir (22) during filling and in this way to make the quantity of first liquid to be measured precise, the reservoir (22) is provided with a valve (23) on the underside and a valve (26) on the top inside the clock (24) which are controlled by the pressure differences in the branch (25) so that when filling, when there is a low pressure or underpressure, the valve ( 23) is closed and the valve (26) is opened so that air can escape and no overpressure is created inside the clock (24), and wherein valve 23 is shut off so that no liquid flows out of the reservoir (22) during filling and so the liquid to be measured is accurately determined and as soon as the liquid outlet opening (27) to the reservoir is closed, the excess pressure in the branch opens the valve (23) and closes the valve (26) so that liquid can flow out of the reservoir and no air is allowed under the clock. A device according to 2 and 3, characterized in that in order to prevent partial emptying of the reservoir (28) during filling and in this way to make the quantity of first liquid to be measured exactly, the reservoir (28) is provided with a valve (29) which is controlled by the pressure differences in the branch (31) so that during filling, when a low pressure or underpressure is created, the valve (29) is closed, so that no liquid flows out of the reservoir during filling and thus the respective liquid to be measured is accurately determined and as soon as the liquid supply (32) to the reservoir (28) is closed, the excess pressure in the branch (31) opens the valve (29), so that the measured amount of liquid from the reservoir (28) ) can flow.