NL193280C - Device for preparing CO2 impregnated water, intended for watering plants. - Google Patents

Abstract

1. Process for the preparation of watering water for household or hobby gardeners, in which the watering water is impregnated with CO2 and fertilizer is dissolved in the impregnated water, characterized in that the water is taken from a normal mains supply pipe at the pressure and the temperature of the pipe and is first conveyed into a control zone in which, by means of the present pressure of the water flowing in, a closing and pressure regulating valve of a CO2 pressure gas source is adjusted, and in that the water is conveyed from the control zone to the entrance end of an impregnation zone which is in the form of an elongated, straight, flow route and in which at least two shoulder-like cross-sectional widenings of the flow route, which widenings are at a distance from each other, the pressure of the water is abruptly lowered and the areas of the water-flow from lowered pressure to the drawing in of CO2 gas into the water stream are brought into contact with a distribution zone via thin, open bores corresponding to the width of the shoulder and being situated in the cross-sectional plane connecting to the annular shoulder, into which distribution zone is conveyed the CO2 gas with the gas pressure controlled by the water inlet pressure, and in that the water is brought into contact with the liquid or solid fertilizers directly after the contact areas with the CO2 distribution zone.

Description

1 193280

Device for preparing water impregnated with CO2, intended for watering plants

The invention relates to a device for preparing CO2-impregnated water, intended for watering plants, which device can be connected to a conventional water pipe and is equipped with a gas cylinder for CO2 gas under pressure, which is provided with a closing and pressure regulating valve, the gas passage of which is adjustable depending on a membrane that can be loaded by the water supply pressure, wherein a mixing space is present for impregnating CO2 gas in the water flow.

Such a device is known from US-A-3,874,277, which device forms part of an installation for preparing mineral water. The diaphragm loadable by the water supply pressure for adjusting the gas passage of the closing and pressure regulating valve is loaded in the closing direction by a set of springs, which ensure that the position of the diaphragm in the mixing space is kept constant regardless of changes in the water supply pressure and therefore also the gas passage of the closing and pressure regulating valve determined by the position of the membrane 15.

The object of the invention is to provide a device of the above-described type, which provides the housewife or hobby gardener with the option of optimally and inexpensively mixing irrigation water drained from the normal water pipe in any desired quantity in an optimum manner, both with CO2 and with fertilizers. respectively, wherein the gas passage opening of the closing and pressure regulating valve can directly follow the pressure variations in the water supply.

This object is achieved according to the invention in that the mixing space is in the form of an injector, which on the one hand communicates with a control chamber which can be connected to the inlet of a conventional water pipe, a wall of which is formed by the pressure control acting on the water supply pressure diaphragm and which, on the other hand, is connected to a gas distribution chamber, which communicates with the shut-off and pressure regulating valve, the control chamber outlet being connected to one end of an elongated straight flow channel, viewed in the flow direction, at least two spaced-apart places are widened to form narrow annular shoulders and in which the planes adjoining the annular shoulders divided in a circumferential series of the cross-section widenings, bores corresponding to the width of the shoulder into 30 free flow connection to the CO2 gas distribution chamber, wherein the a The measurements of the annular shoulders and the pressure controlled in the CO2 gas distribution chamber depending on the water supply pressure are chosen such that a sudden pressure drop is generated at the height of the annular shoulders to draw the gas into the water flow, while the flow channel in an area behind a water / gas contact surface is provided with a contact zone between the water flow and a fertilizer supply.

In the device according to the invention, the impregnation of CO2 in the water flow takes place at various locations in an injector, which is connected to both the water outlet of the control chamber and to the CO2 gas distribution chamber separated from it by the pressure controller, which leads to an extremely fine impregnation of CO2 in the water flowing through the injector tube, which is used directly as irrigation water.

The invention is based on the fact that, in the household or when gardening as a hobby, the irrigation water is usually drawn from the water pipe via a tap. As is known, the water pressure in such pipes is subject to considerable fluctuations. These fluctuations are automatically taken into account in the device according to the invention in order to maintain a fixed setting for the fine impregnation with CO2 gas and for dosing the fertilizer, without the operator having to do more than ensure sufficient stock of gas and fertilizer. It is only necessary to open the tap when there is a need for irrigation water, or to close it when sufficient irrigation water has been drained.

Since in the means used for impregnating water with CO2 gas according to the invention, the gas is dissolved in the water in an extremely stable manner, well reproducible ratios as regards the CO2 content and the fertilizer content are always obtained, despite the very simple design. and operation of the device. Influences of the varying pressure on the dosing accuracy are reliably switched off by the device. The absorption and mixing of the CO2 gas is achieved by the instantaneous reduction of the static water pressure in narrowly defined areas of the outer liquid layers when flowing along the shoulder-shaped cross-sections of the flow path in the impregnation zone and by the small shoulder width corresponding to the and 55 determined open boreholes which bring these outer fluid layers into direct contact with the CO2 gas distribution zone.

The device can be made very compact as an equipment block, which can easily be connected to a conventional water pipe and the outlet of which can be designed directly as a tapping point.

It is noted that DE-C-866.341 discloses a device for introducing CO2 into the pressure water supply pipe of a sprinkler system by means of an injector that is not further described.

5

Embodiments of the device according to the invention are further elucidated with reference to the drawing. Herein: figure 1 shows a cross-section of a first embodiment; and figure 2 shows a cross-section of a modified embodiment.

10

In the embodiment according to figure 1 a housing 1 is provided, provided with a connection 2 for connecting the housing 1 to a usual water supply pipe. Such a supply line connection is normally equipped with a shut-off valve. A control room 3 is present in the housing 1, into which the water enters from the pipe. Depending on the respective supply line 15, the inlet pressure of the water can vary within wide limits, for instance between 100 kPa and 700 kPa. Likewise, the prevailing temperature of the withdrawn water can also be very different.

The prevailing pressure of the water in the control chamber 3 is on a membrane 4, which acts via an operating ram 8 directly on the movable member 7 of the outlet and reducing valve of a CO2 pressure vessel 6, for example a conventional gas cylinder. The pressure vessel 6 equipped with this valve need only be screwed in a sealing manner to the normalized connection of the housing 1 present for that purpose. Such a valve closes automatically if no control pressure is exerted on the valve member 7 from the outside.

Under the membrane 4, a gas distribution chamber 5 is present in the housing 1, which communicates with a gas chamber 10 via a throttle opening 11.

Furthermore, a flow channel 13 is present in the housing 1, the inlet side 14 of which is in open communication with the control chamber 3. The flow channel 13 is preferably straight and elongated and flows into a connection 28 at the bottom end. pouring liquid drain, for example, for filling watering cans or other reservoirs. However, an ordinary garden hose or the like can also be connected to the connection 28.

In a first part, the flow channel 13 has a number of channel parts, the diameter of which increases progressively. These parts functioning as an injector nozzle are indicated by 15a to 15c. In the plane following the collar-shaped widening, the flow channel has a series of connection openings 17, which are in open flow connection with distribution channels 12, which in turn are connected to the gas chamber 10.

In another region of the flow channel 13 located in front of the outlet 28, other corresponding parts 16a, 16b with stepped enlarged diameter are provided. Here, too, bores 18 are present in the plane immediately following the widened shoulder, which are in open flow connection with distribution or connecting channels 19. These connecting channels 19 are connected at their lower end to an area of the flow channel 13 some distance behind the last injector nozzle 16b via bores 20.

40 In the flow channel 13, from above, centrally and at a radial distance from the wall of the flow channel, a supply tube 25 is inserted, which is connected via a blocking or dosing valve 26 to a fertilizer supply for liquid manure and at the location of one of the injector nozzles 15a -16b flows out. In the example shown, the mouth 27 is located at the injector nozzle 15c.

The described device works as follows: 45 When tap water is required, the tap of the supply line, which is connected to the housing 1, is opened. The water entering the housing 1 upon opening fills the control chamber 3 and loads the membrane 4 with the prevailing pressure.

The diaphragm 4 serving as pressure control is designed and sized such that already at a pressure of 100 kPa in the control chamber 3, the reducing valve 7 of the pressure vessel 6 opens and CO2 with a pressure in the chamber reduced by 50 in accordance with the pressure in the control chamber 3. 5 can flow out. The throttling device 11 ensures that the outflowing CO2 gas can only enter the flow channel 13 when the water from the control chamber 3 has entered the flow channel 13 and fills it in a flowing manner. When the flow channel 13 flows through, a sudden drop in pressure in the water flow forms at the location of each stepped diameter change. Due to the reduced pressure, gas from the gas chamber 10, 12 is drawn in and efficiently mixed in the water in very finely divided form and avoiding large bubbles. This fine impregnation is repeated with each injector nozzle 15a-15c. After impregnating the water in this way, fertilizer is supplied to the water in the flow channel 13 and

Claims (6)

3 193280 intimately mixed with the water. The very fine impregnation and the intimate mixing is still considerably enhanced by the following injector stages 16a and 16b, because in these areas a new mixing of the mixing liquid entering through the bores 20 in the connecting channels 19 with the new influx flowing from the injector nozzle 15c mixed liquid occurs. The inlet diameter for fertilizer can be adjusted by throttling through valve 26. The supply pressure of liquid manure can be set directly or indirectly by the instantaneous pressure in the control chamber 3. A simple adjustment of the volumetric supply of fertilizer per water quantity is achieved by allowing the pressure controlled by the control chamber 3 in the gas chamber 10 or 12 to act on the head space of the fertilizer supply or on the outside of a flexible vessel receiving the supply. As a result, a pressure-dependent fertilizer supply and also the beginning and the end of the fertilizer supply are obtained in direct dependence on opening or closing the tap of the supply line. The water pressure itself can also advantageously be used directly for emptying the fertilizer vessel. However, as Figure 2 shows, the underpressure prevailing in one or the other injector stage 33 can also be used to draw the fertilizer pressure-dependent from a storage vessel 38 via the suction line 36 and the riser 39, while at the same time the suction of the gas takes place via the gas chamber 32, 34. Instead of causing the fertilizer to be drawn from an injector nozzles 33 serving for the admixture of gas, a separate injector stage may also be provided between the injector groups 33 and 35, which serves exclusively for the intake of fertilizer. The suction according to figure 2 can also take place together with the pressure of the fertilizer supply by the CO2 gas pressure in the gas chamber 32, 34. In the embodiment according to Figure 2, a housing 30 is again present, which contains all essential parts and connections of the device and thus makes a particularly simple control possible. 25 Contrary to the new method, a water-soluble solid fertilizer can also be used instead of a liquid manure. In this case, the housing is designed such that the water flow through the flow channel 13 according to Figure 1 sprays the solid fertilizer and dissolves an amount of fertilizer corresponding to the amount of water. The valve 7 is practically a simple shut-off valve, which is kept in its blocked position by the internal pressure in the vessel 6. The internal pressure is, for example, 6000 kPa and can fluctuate depending on the temperature. The surface ratio of the sealing surfaces of valve 7 and membrane surface is, for example, about 1:60. The vessel is closed at atmospheric pressure in the device. If the water pressure acts on the diaphragm, this increases the pressure effect, which transfers the diaphragm to the valve by a factor of 60. 35 The valve opens, gas (CO2) flows into chamber 5, the flow of which, as already described, is throttled. . With respect to a pressure-controlled pressure reducing valve, in which the spring pressure remains substantially the same, the membrane 4 transmits all fluctuations in the water pressure and thus controls the CO2 supply depending on the water pressure and the fluctuations thereof. 40 With a small appliance, it must be taken into account that gas bubbles of too large dimensions are still present when leaving the impregnation system. These gas bubbles must be filtered off in such a way that they are supplied to the gas impregnation space so that they are not transported to the delivery point. This would mean that large bubbles escape into the atmosphere and thus the efficiency in terms of gas consumption would be adversely affected. 45 This can be prevented by installing a spiral, but better by installing a meandering system, which runs perpendicular to the system, with the highest point ending in the gas space. One or more gas outlet openings may be provided at this location to allow the lighter gas to escape into the top point so that it can be fed back into the gas space of the injector system, while the filtered and finely impregnated water is supplied to the delivery zone 50 transported. 55 Device for preparing CO2-impregnated water, intended for watering plants, which device can be connected to a water pipe and is equipped with a gas cylinder for CO2 gas under pressure, which is provided with a closing and pressure regulating valve, the gas passage of which is adjustable in dependence on a membrane loadable by the water supply pressure, wherein a mixing space is present for impregnating CO2 gas in the water flow, characterized in that the mixing space is in the form of an injector, which, on the one hand, is connected with a control chamber (3) connectable to the inlet (2) of a conventional water pipe, a wall of which is formed by the pressure control membrane (4) acting in dependence on the water supply pressure, and which, on the other hand, is connected to a gas distribution chamber (12), communicating with the shutoff and pressure control valve (7), the outlet (14) of the pilot chamber (3) connected to one end of a long stretched straight flow channel (13) which, viewed in the flow direction, is dilated in at least two spaced apart locations to form narrow annular shoulders and in which the planes adjoining the annular shoulders are formed by a series of circumferentially of the cross-section widenings (15a, 15b, 15c) bores (17) corresponding to the width of the shoulder are in free flow communication with the CO2 gas distribution chamber (12), the dimensions of the annular shoulders and the dependent of the water supply pressure controlled pressure in the CO2 gas distribution chamber such that a sudden pressure drop is generated at the annular shoulders to draw the gas into the water flow, while the flow channel (13) is in an area behind a water / gas flow. contact surface is provided with a contact zone between the water flow and a fertilizer supply (25). Hereby 2 sheets drawing