NL1023450C2 - Stand alone water disinfection unit, contains UV reactor on fluid connection between water storage tank and outlet - Google Patents

Abstract

A UV reactor (8) powered via a solar panel (12) and/or external electricity source is used to disinfect water passing along a fluid connection (6) between a storage tank (2) and the unit outlet (4). A stand-alone water disinfection unit contains at least one water storage tank, an outlet for dispensing water and a fluid connection between the tank and outlet. The fluid connection includes at least one UV reactor and at least one valve (10) for sealing the connection. At least one solar panel is used to generate electricity and/or an external electrical input is provided. A control device (14) connected to the solar panel and/or external electrical input is used to activate the UV reactor in order to generate UV radiation for disinfecting water flowing towards the outlet when the valve is open.

Description

TiteU, Stand-alone water disinfection unit.

The invention relates to a device for disinfecting water.

Providing clean drinking water in third world countries is an important point of attention for WHO, Unesco and various aid organizations. It is known that with the use of clean drinking water the number of child deaths decreases as well as the risk of diseases and various infections.

Ultraviolet disinfection technology has been successfully applied on a large scale in water treatment plants for cities and 10 factories, among others. A major advantage of ultraviolet technology is that disinfected drinking water can be obtained without the use of chemicals.

It is an object of the invention to provide a means so that the ultraviolet disinfection technology can also be rapidly applied to any desired position in the world and in particular developing countries.

Accordingly, the invention relates to a stand-alone water disinfection unit provided with at least one water storage tank, an outlet for dispensing water from the storage tank and a fluid connection extending from the water storage tank to the outlet, the fluid connection being provided with at least one UV reactor and at least one valve for closing and releasing the fluid connection, the unit further comprising at least one solar panel for generating electrical energy and / or an external electrical input and a control device which is electrically connected to the solar panel and / or the external electrical input and the UV reactor, wherein the control device is adapted to activate the UV reactor for generating UV while supplying the electrical energy from the solar panel and / or the external electrical input - 1023450 I 2 I radiation and wherein the UV reactor is arranged for the irradiate with the UV radiation in the activated state and thereby disinfect the water that flows from the storage tank via the UV reactor and the valve to the outlet I when the valve is opened.

With the aid of the stand-alone water disinfection unit according to the invention, water can be processed in a simple and rapid manner at any desired position in the world in order to obtain disinfected drinking water. Thanks to the fact that it is a stand-alone water disinfection unit, it can easily be transported to a place where drinking water is needed. Furthermore, contrary to what is the case I with known drinking water installations, no time-consuming construction and / or installation I is required. Moreover, if the stand-alone water disinfection unit is provided with the solar panel, even an electricity supply is not necessary, as a result of which the flexibility in the applicability of the stand-alone water disinfection unit is further increased.

In particular, it further holds that the outlet is lower than a highest point of the storage tank so that when the valve is open and the storage tank is filled above a level corresponding to the outlet, water flows from the storage tank out of the outlet when the valve is H 20 open. This has the advantage that when the storage tank is filled with I water, no pump and therefore no electricity is required for tapping I water. This implies that relatively more electrical energy can be used to feed the UV reactor. Preferably, it holds that the outlet is lower than a lowest point of the bottom of the storage tank. In this way, the storage tank can completely drain without using a pump when the valve is opened.

In particular, it further holds that the unit is further provided with H a filter for filtering water with which the storage tank is filled.

With the aid of the filter, the water can be filtered which is supplied to the storage tank 30 so that clear water 3 is present in the storage tank. When the water is clear, the killing of bacteria with the aid of ultraviolet radiation can be carried out relatively more efficiently than when the water is not clear because the water is contaminated with, for example, sand and clay particles.

Preferably, it further holds that the unit is further provided with a battery for storing electrical energy that has been gained with the solar panel. As a result, even when no light is temporarily present, for example at night and when the unit is moreover not provided with the external access or when no electricity supply is present on site, the stand-alone water disinfection unit can still be used to provide drinking water.

The invention will now be further elucidated with reference to the drawing. Herein Figure 1 schematically shows a first embodiment of a stand-alone water disinfection unit according to the invention. Figure 2 schematically shows a second embodiment of a standalone water disinfection unit according to the invention. Figure 3 schematically shows a third embodiment of a standalone water disinfection unit. unit according to the invention! Figure 4 schematically a fourth embodiment of a stand alone water disinfection unit according to the invention! figure 5a shows a practical embodiment of the stand-alone water disinfection unit according to one of the figures 1-4 in a partially dismantled form! Figure 5b shows a cross-section of a part of the device according to figure 5a! figure 5c shows a cross-section of a part of the device according to figure 5a! figure 5d shows a cross-section of a part of the device 30 according to figure 5a! and FIG. 5e a plate which, in use, is placed in a filling opening of the I devices according to FIGS. 1 * 5d.

In Figure 1, reference number 1 denotes a stand-alone I water disinfection unit according to the invention. The unit 1 is provided with a water storage tank 2, and outlet 4 for dispensing water from the storage tank 2 and a fluid connection 6 which extends from the water storage tank 2 to the outlet 4.

The fluid connection 6 is provided with at least one UV reactor I8 and at least one valve 10 for closing and releasing the fluid connection. The stand-alone water disinfection unit 1 is further provided with at least one solar panel 12 for generating electrical energy and a control device 14 which is electrically connected to the solar panel 12 and the UV reactor 8 by means of I and electrical lines 16 and 18, respectively. .

The control device 14 is adapted to activate the UV reactor 8 with the supply of electrical energy from the solar panel 12. The UV reactor 8 is adapted to irradiate with UV radiation in the activated state and thereby disinfect it from water flowing from the storage tank 2 through the UV reactor 8 and the valve 10 to the outlet 4 when the valve 10 is opened.

In this example, the valve is incorporated downstream of the UV reactor 8 in the fluid compound 6. Furthermore, it holds that in this example the valve is an electrically controllable valve which is connected by means of an electric line 20 to the control device 14 for opening and closing the valve. Furthermore, in this example, it holds that the outlet 4 is lower than a highest point 22 of the storage tank so that when the valve is open and the storage tank is filled above a level corresponding to the outlet, water from the storage tank 2 from the outlet 4 flows when the valve 10 is open. Furthermore, in this example it holds that the outlet 4 is lower than a lowest point 23 of the bottom of the storage tank. This has the consequence that the storage tank 23 can flow completely empty when the valve 10 is opened.

The unit 1 is further provided with a manually operable activator such as a switch 24 which is electrically connected in this example by means of a line 25 with the control device 14. Furthermore, the unit 1 is provided with a filter 26 for filtering water with which the storage tank is filled. In this example, the storage tank 2 is provided with a filling opening 28 on its top side. In the filling opening a plate 30 is placed in which a number of water passage openings 32 are arranged (figure 5e). The filter 26 is designed as a bag filter. A bag filter is a filter which is provided with an envelope 34 in which filter material 36 is arranged. The envelope may, for example, consist of filter paper or woven cloth or a non-woven material. The filter material may, for example, consist of sand. However, other variants of the filter are also conceivable. In particular, it holds that the filter is an x-micron bag filter wherein x is in the range of 0.1 * 10, preferably in the range of 0.3 * 5, more preferably in the range of 0.5 * 2 and even more preferably in the range of 0.75 * 1.25.

The UV * reactor 8 is in this example provided with a cylindrical housing 38 with an inlet opening 40 to which water is supplied from the water storage tank 2 in use and an outlet opening 42 through which water can flow from the UV * reactor 8 to the valve 10. At least one UV lamp 44 is included in the housing 38. The UV lamp 44 is also cylindrical in this example and has an outer diameter that is smaller than the inner diameter of the housing 38.

In this example, an axial axis of the UV lamp 44 coincides with an axial axis of the housing 38 so that in use, water flowing through the UV * reactor 8 flows along an outer wall of the UV lamp 44. The UV * reactor is also provided on an inner side 46 of the housing 38 with a metal screen 48 which is also cylindrical in this example. The screen is shown in dotted lines in the drawing.

The UV reactor is furthermore provided with a per se known HF · I stabilizer 50 which is connected to the UV * lamp 44 for converting a DC voltage which in use by the control device via line I 18 to the UV * reactor 8 is supplied to a voltage suitable for driving the UV lamp. The device is further provided with a battery 52 for storing electrical energy that has been gained with the solar panel 12.

The device described up to this point works as follows. First of all, the water storage tank is filled with water. This is generally uncleaned water originating, for example, from a river, a lake, a ditch, etc. This water is supplied to the filter 26 at the top. This water then flows through the filter 26 through the passage openings 32 in the plate 30 to the storage tank 2. Any particles such as dust particles, sand and clay particles that are present in the water are removed from the filter by means of the filter 26 filtered water. The result is that the water storage tank 2 is filled with clear water. This water does not have to be bacteria-free. Electric energy is extracted with the help of the solar panel 12. This electrical energy is supplied to the control unit 14. In this example, the battery 52 is charged with the aid of this electrical energy. When a user wishes to disinfect disinfected water, he energizes the switch 24. In response to the energizing of the I switch 24, the control device 14 opens the valve 10. Also, I 25 activates the control device 14 in response to the energizing of the switch H 24 via line 18 the UV reactor. The electrical energy that the control device 14 requires for this is either obtained directly via line 16 of the solar panel 12 or obtained from the battery 52 or a combination of both. The energy stored in the battery 52 is also obtained with the aid of a solar panel so that in this example the energy in question comes directly or not directly from the solar panel 12.

When the UV reactor is activated, the ultraviolet lamp 44 starts to burn and emits ultraviolet radiation. Because the valve 10 is opened, water will flow from the storage tank 2 via the fluid connection 6 to the outlet 4. This water flows through the UV reactor 8. In this example, the water flows through a space that is present between the UV lamp 44 on the one hand and the inside 46 of the housing 38 of the reactor on the other. The said ultraviolet radiation is present in this space. This is held within the housing 38 by the shield 48. The result is that any bacteria present in the water in the UV reactor 8 can no longer propagate. The water leaving the reactor 8 is thus, at least practically, free from harmful bacteria. The result is that disinfected water is dispensed via outlet 4.

When sufficient disinfected water has been tapped, a user can re-energize or release the switch 22, all depending on the specific embodiment, with the result that the control device 14 closes the valve 10 and deactivates the UV reactor 8 so that UV-no longer radiation is generated. This implies that the UV lamp 44 will go out. Because the lowest point of the outlet 4 is located below the lowest point 24 of the bottom of the water storage tank 2, the water storage tank 2 can be completely drained in this way. All this is based on the law of communicating vessels. This also means that the valve 10 and / or the UV reactor 8 can be in a higher or lower position than indicated in the drawing.

When the stand-alone water disinfection unit is used in the dark, the control device 14 will at least substantially dissipate its energy from the battery 52. This battery 52 can then be recharged with the aid of the solar panel 12 when light is present.

Preferably, it further holds that the device is further provided with an external electrical input 54 which in this example is connected to the control unit 14 by means of a line 56. Electrical energy can be supplied to the control unit 14 via this external electrical input to replace or supplement the electrical energy obtained with the aid of a solar panel. With this external electrical energy, the battery 52 can be charged and / or the valve 10 and / or the UV * reactor 8 and / or the control device 14 can be supplied with electrical energy.

In this example, the device is further provided with an information panel 58 which in this example is connected to the control device 14 via line 25. This information panel 58 may, for example, comprise lamps or LEDs 60, which indicate the status of the device. It can thus be indicated that the device I15 is in a heating-up mode. After all, the UV reactor 8 can be of a type which must heat up before the UV lamp 44 can be ignited.

It can also be indicated when the device is ready for use. It can also be indicated when the device has a malfunction, for example when it appears that the UV reactor is not functioning properly.

To this end, the control device 14 can be provided with control electronics known per se which, by means of line 18, investigates whether the UV reactor functions properly H. The control device also ensures that when a UV lamp is used which has to heat up, when the switch 24 is energized, the UV lamp is first preheated and is started after some time delay, whereby the valve 10 is then also started after some time delay so that the UV lamp has already started when water starts to flow into the UV reactor.

In this example, the valve 10 is included downstream of the UV reactor. However, it is also possible that the valve 10 is included in the fluid communication 6 between the water storage tank and the UV reactor 8. All this is shown in FIG. 2. The device is furthermore entirely analogous as in relation to FIG. 1 has been described.

It is also possible, as shown in FIG. 3, that the valve 10 is designed to be manually operable by means of an operation 62. In this example, the stand-alone unit is then further provided with a sensor 64 which is included in the fluid connection 6 and in this example in the valve 10 to detect that the valve is open or that water flows through the fluid connection 6. This sensor 64 is connected to the control device 14 via an electrical line 16. When the valve 10 is opened by means of the control 62, water will flow through the fluid connection 6 from the storage tank 2 via the UV reactor 8 and the valve 10 to the outlet 4. The sensor 64 detects in this example that the valve 10 is open. In response thereto, control device 14 activates the UV reactor 8 via line 18 as described above. When the valve 10 is closed again with the aid of the control 62, this is also detected with the aid of the sensor 64. In response thereto, the control device 14 will switch off the UV reactor 8, i.e. the UV lamp 44 will go out. In this example, in FIG. 3 then the switch 22 is no longer present. The line 24 is still present for the information panel 58. The sensor 64 can of course also be included elsewhere in the fluid connection 6, in which case the sensor 64 is adapted to detect that water flows through the fluid connection 6.

According to an alternative embodiment, as shown in FIG. 4, the stand-alone water disinfection unit is further provided with at least one electric pump 70 for supplying water from the storage tank to the outlet 4 via the fluid connection 6. In that case the outlet 4 can be located at any desired height relative to from the storage tank 2. This basically means that the exemplary embodiments according to Figs. 1, 2 or 3 the valve 10 is replaced by the pump 70. When the switch 24 in FIG. 1 and 2, the pump 70 and the UV reactor 8 are started by the control device 14. Water will be tapped after this. By operating the switch 24, the pump 70 and the UV reactor 8 are then switched off again. In this example, the pump 70 is located downstream of the UV * reactor 8. It is also possible that the pump 70 is located upstream of the UV * reactor 8, i.e. between the water storage tank 2 and UV reactor 8 in the fluid communication. 6 is included.

Such variants are each understood to fall within the scope of the invention.

Furthermore, in particular, as shown in FIG. 1, that the water disinfection unit is further provided with at least one electric pump 72 for supplying water to the storage tank. The pump 72 can, on the one hand, be connected by means of, for example, a liquid line 74 to a water reservoir such as a river and, on the other hand, be connected to the filling opening 28 by means of a liquid line 76. The pump 72 can again be fed from a solar panel. In this example, the I pump 72 is supplied from the solar panel 12 (either directly or indirectly through the intervention of the battery 52) and is connected for this purpose via line 78 to the I control device. It is also possible that the electric pump I 72 is directly connected to the solar panel 12 or the external access 54 for this purpose. Such variants are each understood to fall within the scope of the invention.

How a device according to e.g. 1 can practically look like H is shown in FIG. 5a-5th. In the FIG. 5a-5e are shown in FIG. 1 corresponding parts with the same reference number.

It is noted that FIG. 5a-5e do not show all parts shown in Figs. 1., such as, for example, the control device, the various lines, etc. These have been omitted for simplicity. In this example, the device comprises a receiving space 80 in which, for example, the control device 14 and the HF stabilizer 50 can be accommodated.

I m? 345n 11

The invention is in no way limited to the embodiments outlined above. For example, other types of UV * reactors can be used, other types of valves, etc. The control device 14 can consist of various sub-modules that are mutually electrically connected to each other. However, it is also possible that the control device 14 consists of a single integrated module. Said sub-modules can be arranged at different positions in the stand-alone water disinfection unit and then functionally form the control device 14 but do not need to be physically provided with a single housing of the control device 14. Optionally, the plate 30 can be replaced by a bag filter. A bag filter can also be positioned on the plate 30. The solar panel 12 can also be omitted, whereby the unit receives its energy via the external access 54. Such variants are each understood to fall within the scope of the invention.

Claims (18)

A stand-alone water disinfection unit, comprising at least one water storage tank, an outlet for dispensing water from the storage tank and a fluid connection extending from the water storage tank to the outlet, the fluid connection being provided with at least one UV reactor and at least one valve for closing and releasing the fluid connection, the unit further comprising at least one solar panel for generating electrical energy I and / or an external electrical input and a control device that is electrically connected to the solar panel and / or the external electrical input and the UV reactor, wherein the control device is adapted for activating the UV- energy from the solar panel and / or the external electrical input while supplying the electrical energy I reactor for generating UV * radiation and wherein the UV reactor is adapted to be in the activated state irradiating with the UV radiation and thereby disinfecting the water that flows from the storage tank via the reactor and the valve to the outlet when the valve is opened. A stand-alone water disinfection unit according to claim 1, characterized in that the outlet is lower than a highest point of the I storage tank so that when the valve is open and the storage tank is filled to a level above I corresponding to it with the outlet water from the storage tank flows out of the outlet when the valve is open. 3. A stand-alone water disinfection unit as claimed in claim 2, characterized in that the outlet is lower than a lowest point of the bottom of the storage tank. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the valve is included in the fluid communication downstream of the UV reactor. 5. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the valve is an electrically controllable valve connected to the control device for opening and closing the valve, the control device activating the UV reactor when the valve is opened by the control device. 6. A stand-alone water disinfection unit according to claim 5, characterized in that the unit is furthermore provided with a manually operable activator which is electrically connected to the control device, the control device activating the UV reactor and opening the valve when the activator is energized. 7. A stand-alone water disinfection unit according to any one of the preceding claims 1-4, characterized in that the valve is designed to be manually operable, wherein the device is further provided with a sensor for detecting that the valve is opened or that water flows through the fluid connection with the sensor connected to the control device and the control device activating the UV reactor when the sensor 20 detects that the valve is open or that water flows through the fluid connection. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the unit is further provided with a filter for filtering water with which the storage tank is filled. A stand-alone water disinfection unit according to claim 8, characterized in that the filter is provided with a bag filter. A stand-alone water disinfection unit according to claim 9, characterized in that the filter is a mic-micron bag filter wherein x is in the range of 0.1-10, preferably in the range of 0.3 * 5, more preferably in the range of 0.5-2 and even more preferably in the range of 0.75 * 1.25. 1nOQARn I 14 11. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the UV reactor is provided with at least one UV lamp and at least one HF stabilizer connected to the UV lamp for the purpose of converting a DO voltage to a voltage I 5 suitable for driving the UV * lamp. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the UV reactor is provided with a metal shield for retaining the UV radiation within the reactor. 13. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the unit is further provided with a battery for storing electrical energy that has been gained with the solar panel. 14. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the unit is further provided with at least one electric pump for supplying water to the storage tank. Stand-alone water disinfection unit according to claim 14, characterized in that the electric pump is electrically connected to the solar panel and / or the control device and / or the external electrical input. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the unit is further provided with at least one electric pump for supplying water from the storage tank to the outlet via the fluid connection. 17. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the unit is further provided with an information panel connected to the control unit to indicate at least I whether the unit is ready or not ready for use. . 18. A stand-alone water disinfection unit according to any one of the preceding claims, characterized in that the unit is provided with the external electrical input for supplying electrical energy to the control unit to replace or supplement the electrical energy supplied with with the help of the solar panel. 1023450