CH698955B1 - System for disinfecting air in ventilation channel of air conditioning system, has galvanic electrolyte in which silver ion containing aqueous solution is formed, and tank to which disinfectant is delivered by suction pump - Google Patents

Abstract

The system has atomizer nozzles (8) connected with a tank (12) and a pump (13), and needle-shaped ionization electrodes (6) attached to a ventilation channel (1) to ionize air and charge disinfectant particles, which atomize and float in the channel. Walls (2) of the channel are earthed. Another tank (23) contains water that is delivered into a galvanic electrolyte (18) by a supply pump (24). A silver ion containing aqueous solution, which serves as a disinfectant (9), is formed in the electrolyte. The disinfectant is delivered to the tank (12) by a suction pump (17).

Description

       

  The present invention relates to a system for disinfecting the air in a ventilation duct of an air conditioner by means of an aqueous disinfectant, wherein the system comprises a device with atomizing nozzles, which are connected to a first tank for the disinfectant and a first pump and wherein in the ventilation channel needle-shaped ionizing electrodes are attached, which ionize the air and charge the air in the ventilation channel floating, atomized disinfectant particles, the electrodes are connected to a high voltage source and that the walls of the ventilation channel are grounded.

  

A system of the type mentioned is known from EP-A-0 615 603. The system has proven itself in the function well. So far, the plant was operated with quaternary ammonium compounds as a disinfectant. The disinfectants to be used are subject to strict health control requirements. These disinfectants must under no circumstances contain mercury, phenol or similar substances. Furthermore, the volatiles usually contained in disinfectants must not be flammable. Thus, flammable volatile components are automatically not allowed. As a result of ionization, it should also contain no alcohol. From these considerations one has come to the quaternary ammonium compounds.

   In experiments, compounds such as benzyl ammonium chloride, N-octyl dimethyl and 1,1,3,3-tetrabutyl-phenoxy-ethyldimethyl or 1,1,3,3-tetrabutyl-ethoxydimethyl-benzyl-ammonium chloride have been proven.

  

Although these disinfectants are considered to be free of toxic substances, but almost always require the national approval. Corresponding approval procedures are extremely time consuming and costly. In addition, these disinfectants are always distributed in aqueous solution diluted accordingly. Depending on the degree of dilution, this leads to considerable selling costs since correspondingly large quantities of water are transported. Although it is possible to deliver the disinfectant in high concentration and then let dilute only by the consumer. However, this requires that the people assigned to it work accordingly carefully and are concerned for a continuous supply.

   This not only requires topping up the mixture and preparing the mixture, but of course, early ordering to ensure replenishment.

  

It is therefore the object of the present invention to modify a system of the type mentioned in such a way that the aforementioned difficulties no longer arise.

  

This object is achieved by a system having the features of the preamble of claim 1, which is characterized in that the system has a further, second tank, in which water is contained, which is conveyed via a second pump into a galvanic bath, in which the water is enriched with silver ions to form the disinfectant, which is then conveyed via the first pump in the first tank.

  

Further advantageous embodiments of the subject invention will become apparent from the other dependent claims and their operation will be explained in the following description with reference to the accompanying drawings.

  

The basic idea, which is realized in the invention, is to improve a plant of the type mentioned in such a way that the disinfectant to be used by the plant itself can be generated locally.

  

As an equivalent solution, a system for disinfecting the air in a ventilation duct of an air conditioner according to the preamble of claim 1 may also be designed so that the system is connected via a reducing valve with a water pipe, and that a cartridge is present on the Water is enriched with silver shares and that this silver-enriched water in the first tank is conductive.

  

The strong antibacterial effect of silver has long been known and has been approved since 1992 by the US Department of Health for use in drinking water. Already for the Apollo flights an ionization system was developed in which electrolytic silver ions were added to both the drinking and the sewage system. The released silver ions effectively eliminated bacteria and viruses. The present invention has made use of this finding.

  

With the advent of nanotechnology, it was also possible to enrich plastics with silver and produce from such, enriched with silver plastics cartridges with which water can be sterilized. In an alternative solution according to claim 9 use is made of this knowledge.

  

In the accompanying drawings two embodiments of the subject invention are shown schematically and explained with reference to the following description. It shows:
<Tb> FIG. 1 <sep> the scheme of a plant in which the silver is produced in the form of silver ions in a galvanic bath, and


  <Tb> FIG. 2 <sep> a plant in which the silver is discharged by means of commercial cartridges into the water, which serves as a disinfectant.

  

As already apparent from the introduction to the description and the figures list, two different principles are shown, but these differ only in relation to the generation of the water provided with silver ions, which serves as a disinfectant. As mentioned above, to be disinfected by means of the inventive system air in a ventilation duct of an air conditioner. The air conditioner is shown in the drawing only by a portion of a ventilation duct 1. The ventilation channel is limited by the walls 2 of the channel. Through the ventilation duct 1 and thus through the air conditioning air flows, which is symbolized by the arrow 3.

   Since the flow rate is proportional to the amount of air flowing through the air conditioner, it must be determined if there is any flow of air at all and, if so, how big this flow is. For this purpose, a flow meter 4, which communicates with a control unit 10 is used. The amount of the disinfectant 9 to be sprayed is correspondingly in relation to the air flow 3. In the flow direction here follows the flow meter 4, a high voltage electrode 6, which is fed by the control unit 10, in which a high-voltage controller 11 is integrated. Experience has shown that the high voltage applied to the electrode 6 is to be kept below a voltage of 10,000 volts to avoid a relevant ozone content.

   In principle, the voltage and thus the release of electrons will be reduced when the airflow 3 decreases. The free electrons are blown downstream with the air flow in the flow direction of the ventilation duct 1. Since, of course, free electrons also hit the walls 2 of the ventilation duct 1, this must be in contact with a grounding 5. With respect to the electrode 6, a sputtering device 7 is arranged downstream in the ventilation channel 1. The atomizing device 7 is provided with corresponding atomizing nozzles 8. The atomizer nozzles 8 are directed in the direction against the air flow 3.

   Experiments have shown that the seemingly logical arrangement to arrange the nozzles so that they atomize the disinfectant downstream, that at already slightly higher flow rates, the air flow 3 is practically the atomizing cloud and thus a turbulence of the atomized disinfectant particles with the Anions enriched air hardly mixed but that it is transported through the ventilation channel 1 practically separated. In the plant preferred here and known from EP-A-0 615 603, an absolutely perfect mixing is produced by the countercurrent atomization of the atomizing nozzles. Experiments have also shown that the distance between the sputtering device 7 and the electrodes 6 should be between 1 and 2 meters.

   At the distance mentioned, an optimal mixing of the disinfectant, which contains positively charged silver ions and causes the negative ions released by the electrodes, without, however, causing short circuit breakdowns at the electrodes.

  

The sputtering device 7 receives the disinfectant 9 via a pressure line 14, which is connected to a first tank 12. A pressure pump 13, which is controlled by the control unit 13, pumps the disinfectant 9 from the first tank 12 in the sputtering device 7. The level of the disinfectant 9 in the first tank 12 can be monitored by means of a level float switch 15, which switch in turn with the control unit 10th communicates. According to the level float switch is controlled by the control unit 10, a suction 17, which is interposed in the suction line. The suction line 16 is connected to a galvanic bath 18 in connection. In the galvanic bath 18 plates 19 and 20 are arranged.

   These may be silver plates alone or silver plates on the one hand and copper plates on the other hand.

  

At the cathodes is a positive pole and the anode is a negative pole of a DC power source 21 at. Also, the DC power source 21 is controlled by the control unit 10 in the current. Preferably, as constant as possible a current in the milliampere range is maintained. The water enriched with silver ions, which now represents the disinfectant 9, is conveyed from the galvanic bath 18, as already mentioned, via the suction pump 17 into the first tank 12. The water level in the galvanic bath 18 is then readjusted via a line 22, which can be in operative connection via a feed pump 24 with a second tank 23. The feed pump 24 is in turn controlled by the control unit 10.

  

Alternatively, the line 22 may be directly connected to the water supply network 25, wherein this connection is made via an electrically controlled control valve 26. The control valve 26 is then actuated by the control unit 10 instead of the feed pump 24.

  

The solution shown here has the great advantage that the entire system can operate completely autonomously virtually without maintenance. This is especially true if it is possible to dispense with the second tank and the supply of water to be replenished can be obtained directly from the water supply network 25. This is essentially dependent on national legislation. The second tank 23 may also be provided with distilled water instead of ordinary tap water.

  

Although in the solution shown here and as described above, the electrode 6 is operated so that the high voltage at the electrode does not exceed a value of 10 kV, which usually no ozone levels occur, which are above an accepted limit, can of course Flow direction in the ventilation channel 1 down an ozone sensor may be provided by means of which the ozone content is checked and the control unit 10, the electrode is controlled accordingly.

  

Also not shown here in the drawing, the first tank may be connected to a third tank via a metering pump, by means of which additives the disinfectant 9 can be added. Such additives are especially perfumes.

  

Also, the galvanic bath 18 may have its own control circuit, so as to keep the concentration of silver ions to a predetermined value. However, as already mentioned above, this task can also be assumed by the control unit 10.

  

The use of copper plates and silver plates 19, 20 in the galvanic bath 18 is useful because in particular bacteria and viruses can be destroyed with the presence of silver ions, while the presence of copper ions, especially the algae growth prevents or at least largely stops.

  

If both copper and silver plates are present in the galvanic bath, it will be advantageous to change the polarity of the copper or silver electrodes in the galvanic bath 18 at intervals in order to avoid copper plating or silvering of the plates. A change in polarity at intervals of five minutes in continuous operation has proven to be particularly useful.

  

In the embodiment according to FIG. 2, all elements which are present in the embodiment according to FIG. 1 are provided with the same reference numerals. Accordingly, in turn, the entire air conditioner is represented only by a portion of a ventilation channel 1, which is bounded by the walls 2. Again, the walls 2 are grounded to a ground 5. The air stream 3 is in turn monitored by a flow meter 4 and the data supplied to the control unit 10. The high voltage electrodes 6 are driven and fed by the control unit 10 in accordance with the existing air flow. The same applies to the atomizing device 7, which is also provided here with atomizing nozzles 8, which are directed against the air flow direction.

   The atomizing device 7 is also fed from a first tank 12 via a pressure line 14 by means of a pressure pump 13 here. The pressure pump 13 is controlled by the control unit 10. The first tank 12 is fed by a supply line 22, which in this embodiment is directly connected to the water supply network 25. The supply amount is in turn regulated by a control valve 26, wherein the control valve 26 is controlled by the control unit 10 via the control line 30. The silver ion addition takes place here instead of a galvanic bath through a cartridge 29. In the cartridge 29, a plastic labyrinth is provided, through which the water flows. This labyrinth is made of plastic, which contains the finest silver particles using nanotechnology, which are washed out accordingly.

   Such cartridges are available on the market and today serve to enrich water for swimming pools with silver ions, so as to avoid bacterial or viral infestation of the pool water. The cartridge 29 is connected downstream of an ion measuring device 27 in the flow direction. The ion measuring device, which communicates with a three-way valve, supplies the information to the control unit 10, which in turn switches the three-way valve with insufficient ion delivery so that at least a portion of the already ionized water via a feedback line 28 in the supply line 22 in front of the cartridge 29 returned can be so that at least a portion of the water flows through the cartridge again and thus the ion number is increased.

   Since this type of ion admixture today may be placed practically directly in the pipeline network worldwide, a second tank is unnecessary here as an intermediate buffer.

  

Of course, certain alternatives may also be present here, which have already been discussed above with respect to the embodiment of FIG. 1. In the example shown here, in particular, an additional tank 31 is shown, via which fragrances the disinfectant 9 in the first tank 12 can be admixed.

LIST OF REFERENCE NUMBERS

  

[0024]
<Tb> 1 <sep> ventilation channel


  <tb> 2 <sep> walls of the ventilation duct


  <Tb> 3 <sep> airflow


  <Tb> 4 <sep> flowmeter


  <Tb> 5 <sep> Grounding


  <Tb> 6 <sep> electrodes


  <Tb> 7 <sep> atomizing


  <Tb> 8 <sep> atomizing


  <Tb> 9 <sep> Disinfectants


  <Tb> 10 <sep> control unit


  <Tb> 11 <sep> High Voltage Control


  <tb> 12 <sep> first tank


  <Tb> 13 <sep> pressure pump


  <Tb> 14 <sep> pressure line


  <Tb> 15 <sep> level switch


  <Tb> 16 <sep> suction


  <Tb> 17 <sep> suction pump


  <tb> 18 <sep> galvanic bath


  <Tb> 19 <sep> Plate


  <Tb> 20 <sep> Plate


  <Tb> 21 <sep> DC power supply


  <Tb> 22 <sep> Line


  <tb> 23 <sep> second tank


  <Tb> 24 <sep> feed pump


  <Tb> 25 <sep> water mains


  <Tb> 26 <sep> control valve


  <Tb> 27 <sep> Ion Meter


  <Tb> 28 <sep> feedback line


  <Tb> 29 <sep> cartridge


  <Tb> 30 <sep> control line


  <Tb> 31 <sep> additional tank


    

Claims (10)

1. Plant for disinfecting the air in a ventilation duct (1) of an air conditioning system by means of an aqueous disinfectant (9), the system comprising a device (7) with atomizing nozzles (8), which is provided with a first tank (12) for the disinfectant ( 9) and a first pump (13) are connected and wherein in the ventilation channel needle-shaped ionization electrodes (6) are mounted, which ionize the air and the floating in the ventilation channel, atomized disinfectant particles, the electrodes (6) are connected to a high voltage source and that the walls (2) of the ventilation duct are grounded (5), characterized in that the installation has a further, second tank (23), in which water is contained, which can be conveyed via a feed pump (24) into a galvanic bath (18) in which a silver ion-containing,  aqueous solution, which serves as disinfectant (9) is formed, which is conveyed via a suction pump (17 in the first tank (12). 2. Installation according to claim 1, characterized in that the system comprises a control device (10) which is connected to an ozone sensor in the ventilation duct (1), which regulates the high voltage source so that substantially no ozone occurs in the air in the ventilation channel. 3. Plant according to claim 1, characterized in that the high voltage source comprises a voltage limiting circuit which controls the voltage of the high voltage source so that the ionizing electrodes operate ozone generating free. 4. Plant according to claim 1, characterized in that the first tank (12) with a third tank (31) is connected via a metering pump for the admixture of fragrances in the disinfectant. 5. Installation according to claim 3, characterized in that the voltage limiting circuit keeps the voltage of the high voltage source to a predetermined value below 10 000 V. 6. Plant according to claim 1, characterized in that the galvanic bath (18) comprises a control circuit with which the concentration of the silver ions can be maintained at a predeterminable value. 7. Installation according to claim 1, characterized in that in the ventilation channel (1) a flow meter (4) is arranged, which via the control device (10) the first pump (13) for metering the supply of the disinfectant (9) to the atomizer nozzles ( 8) regulates. 8. Plant according to claim 1, characterized in that in the galvanic bath (18) an electrode as a copper electrode and an electrode as a silver electrode (19, 20) is formed. 9. Plant for disinfecting the air in a ventilation duct (1) of an air conditioner by means of an aqueous disinfectant (9), wherein the system comprises a device (7) with atomizing nozzles (8) with a first tank (12) for the disinfectant and a first pump (13) are connected and wherein in the ventilation channel needle-shaped Ionisierungselektroden (6) are mounted, which ionize the air and charge the floating in the ventilation channel, atomized disinfectant particles, the electrodes are connected to a high voltage source and that the walls (2) of the Ventilation channels are grounded (5), characterized in that the system via a reducing valve (26) with a water line (25) is connected and that a cartridge (29) is present, via which the water is enriched with silver shares,  and that this silver-enriched water in the first tank (12) is conductive. 10. Plant according to claim 9, characterized in that the silver content at a measuring point (27) after passing through the cartridge (29) is detectable and that after the measuring point (27) a three-way valve is present, by means of which the measured water provided with silver traceable (28), so that this again flows through the cartridge.