DE3743479C1 - Device for removing oxygen - Google Patents

Abstract

The device is intended for removing oxygen from a heat-transfer medium situated in air- or oxygen-permeable heating-circuit systems, in particular floor-heating systems, and consists of a housing through which the heat-transfer medium can flow, with inflow and outflow connections in which oxygen-consuming metal parts or particles are arranged. Such a device is constructed in such a way that the metal parts are in the form of a metal-particle packing (3) which can be inserted into the housing (1), that a sludge-collecting space (4) is kept free between the lower end of the packing (3) and the bottom of the housing (1), that the packing (3) is arranged between the inflow and outflow openings (12, 13), arranged at the top of the housing (1), in such a way that the heat-transfer medium is able to flow through the packing (3) at least with a downwardly oriented flow component, and that the through-flow cross-section of the packing (3) is dimensioned larger than the cross-section of the inflow opening (12). <IMAGE>

Description

The invention relates to a device for removing sow material from the heat transfer medium of air or oxygen permeable heating circuit systems, especially underfloor heating according to the preamble of Main claim.

It is known, so-called parquet for "deacidification" of water to use steel chips. These parquet steel shavings must obviously be in one a flowable housing-like structure, and so far the preamble of the main claim ches related to it.

Open heating Systems (open in the area of the expansion vessels) that however hardly come into consideration as modern facilities are equipped with closed expansion vessels through the possible access of air or air acid  fabric highly susceptible to corrosion. But also with closed systems there is a risk of corrosion if the Use of lines made of plastic oxygen perma nent can diffuse into the heat transfer medium. Corrosion occurs in particular Boiler open, especially since the chemically related cor rosion process is promoted by heat. At the kettle then occurring corrosion damage is often the Boiler manufacturer charged without taking into account that the cause of such damage to others Job is to be looked for.

Based on the existing and mentioned above Knowing that you can free oxygen through water Can escape forced corrosion, the invention is the Task based on a device for air or oxygen permeable heating circuit systems, d. H. in particular Underfloor heating or heating systems to create that easily from the outset or afterwards Lich can be integrated into such systems and its oxygen binding metal parts easily have it replaced or refilled and at the same time ge  should be ensured that the resulting rust sludge remains in the device and not can get into the connected heating circuit.

This task is with a device of the beginning ten kind according to the invention by the in the characteristic of Main claim listed features solved. Advantage sticky and practical embodiments result according to the subclaims.

This device according to the invention thus represents, as it were is a forced corrosion depot, which the concerned Heating circuit is connected downstream where due to the heat transfer medium returning to the heating circuit dium, of free and insofar harmful oxygen is liberated and this oxygen does not Corrosion damage can cause more.

Metals forming the particle packing are those which have a more negative potential than the oxygen redox potential (E ₀ = 0.491 V), e.g. B. Zn, Al, Mg, Fe, steel, GG or the like.

It is essential that these are oxygen-binding Metals in fine distribution, i.e. with the largest possible Surface are present in the device and still in one  placed in the device and for renewal can be exchanged just as easily.

It is particularly advantageous for the removal of oxygen It turned out to be perfect if one differentiated the device Liche metals used, so that an element education arises, which is targeted with the device aspired to the corrosion process caused by oxygen is beneficial. This can be done in different ways become real by looking at the metal particle packing made of different metals or the device housing with respect to which the particles forming metal from other metal or by one also looks for a potential difference between packing and their flow-through cover ensures.

The inventive design of the device made sure that the metal particle packing from the oxygen-contaminated heat transfer medium medium slow, so to some extent reassured by can flow to the one hand, the response time to extend and on the other hand to ensure that the resulting corrosion products better down can settle into the corrosion sludge collection chamber.  

Because from time to time a renewal of the particle packing and removal of the corrosion slurry must be pulled, the device is also advantageous its inflow and outflow connections with Ver valve provided through which both the heating but also the heating circuit in question is closed and the device can be opened easily, for what the device from the wiring harness does not look out for need to build this advantageously with a detachable Cap is equipped.

Also exist for the removal of corrosion sludge different execution options, namely dahinge hend that the collecting chamber like the Metallpar Item pack from the housing with the closure open cover can be removed or that the housing or the collection chamber with a lockable Sludge drain is provided.

The device according to the invention is below based on the graphic representation of execution examples explained in more detail. It shows schematically  

Fig. 1 shows a section through an embodiment of the apparatus;

Fig. 2 also in section another Ausfüh approximate shape of the device;

Fig. 3 shows a preferred embodiment of the device in section and

Fig. 4 in section a multi-chambered Ausfüh approximate shape of the device.

It applies to all embodiments described below that is disposed corrosion sludge collection chamber 4 in the housing 1 below the metal particle packing 3, and the outflow surface of the metal particles pack 3 corresponding to a multiple of the cross section of the Zuströmanschlusses 12th Furthermore, it is provided in all the exemplary embodiments that at least the cover 2 or the pipe section 17 is formed from a material which has a more positive normal potential than the metal particles for activating the corrosion of the metal particles. Furthermore, it can also be provided for all the exemplary embodiments that part of the metal particle pack 3 is made of nobler metal particles, such as non-rusting stainless steel and the other part is made of less noble metal particles, and both types of particles are arranged in the pack 3 in a uniformly distributed manner. In the embodiment according to FIG. 1, the metal particle packing ring-shaped 3, characterized wherein the given central space is formed closed against the sludge collection chamber 4 5, which is located under the package 3. As can be seen further from Fig. 1, the housing 1 has an inlet chamber 6 and an outlet chamber 7, where, therefore, the Me tallpartikelpackung 3 and the sludge collection chamber 4 between the two chambers 6, 7 is such that the inflowing through the inlet connection 12, acidic heat transfer medium must pass the packing 3 radially outwards, in order then to get into the outflow chamber 7 and from there into the outflow connection 13 , which is connected to the heating circuit. The Zuströmkam mer 6 is tightly closed in this example with a solvable lid 8 , which can be removed for the purpose of removing the corrosion sludge and / or exchange of the metal particle pack 3 . The Me tallpartikelpackung 3 and the sludge collection chamber 4 are formed in the form of an overall removable from the housing 1 unit, but the package 3 and the collection chamber 4 are detachable from each other.

The oxygen-binding metal, which is in the form of particles with the largest possible total surface area as a packing, is indicated by dashed lines in FIG. 1 and provided with a flow-through cover 2 on the inflow and outflow sides. For the use of this unit made of metal particle pack 3 and sludge collecting chamber 4 , the partition 10 between the flow chamber 6 and the outflow chamber 7 has a correspondingly dimensioned opening 9 , in which the unit is simply hung as shown and, if necessary, in this position with suitable means (e.g. holding cams on the cover 8 ) is fixed.

Since the entire device is to be installed behind the heating circuit in the return line to the heating circuit, the inflow and outflow connections 12, 13 are equipped with simple shutoff valves 14 in order to be able to separate the device from the circuits for the purpose of cleaning and / or replacing the particle pack 3 .

The embodiment of FIG. 2 differs only in so far from that of FIG. 1, as the sludge collection chamber 4 is an integral component of the housing 1 ' , and the bottom of the collection chamber 4 has a sludge drain 11 . From the dead area 6 'of the inflow chamber 6 , one or more small openings 4'' in the wall 4' of the collecting chamber 4 can lead into this. In both embodiments, it is also possible to omit special collecting chambers 4 and simply remove them from under the pack 3 available space of the Ge housing 1 to use as a collection chamber.

The embodiment according to FIG. 3 is preferred because it is the easiest to implement and also has the advantage that the particle pack 3 is only flowed through from top to bottom, ie the pack is subject to a strictly downward flushing effect, since the pack 3 sits in a pipe section 17 , which is directed with its opening 18 downwards against the floor and into the collecting chamber 4 and is provided with a grid-like holder or pack carrier 19 , provided that the metal particles of the pack 3 are not in another suitable manner in the pipe section 17th being held.

The housing is formed from an upper part 1 '' and a lower part 1 ' (this also applies to the previously described exemplary embodiments), the lower part 1' being detachable but close to the upper part 1 '' provided with the inflow and outflow connections 12, 13 is designed to be closable. The pipe section 17 is also releasably seated in the partition 10 and can thus be easily removed and replaced after removing the lower part 1 ' .

The lower part 1 ' can be formed from transparent material, so that the degree of filling of the collecting chamber 4 is visible. In the exporting approximately example of Fig. 1, 2, this is also possible, please include, in particular, if no special collection chambers are provided, which can also be formed transparent though.

The embodiment according to FIG. 4 is provided in particular for the case in which several underfloor heating circuits are to be connected to one heating circuit. For this purpose, the housing 1 is divided into at least two separate chambers 16 , with a metal particle pack 3 and a sludge collecting chamber 4 each being arranged in the manner described above in each chamber, as shown in simplified form.

Claims (13)

1. Device for removing oxygen from an air- or oxygen-permeable heating circuit system, in particular underfloor heating medium, consisting of a heat-flowable housing with inflow and outflow connections in which oxygen-binding metal are arranged, characterized in that
is that the metal forms as particles in the form of an insertable into the housing (1) Metal particle packing (3) is that a sludge collection chamber (4) is arranged between the lower end of the package (3) and the bottom of the housing (1) that the pack ( 3 ) between the inlet and outlet connections ( 12, 13 ) arranged at the top of the housing ( 1 ) is arranged in such a way that the pack ( 3 ) can be flowed through by the heat transfer medium at least with a downwardly oriented flow component and
that the flow cross-section of the packing ( 3 ) is larger than the cross-section of the flow opening. 2. Apparatus according to claim 1, characterized in that the metal particle pack ( 3 ) in a Ge in the housing ( 1 ) interchangeably inserted pipe section ( 17 ) is arranged, the lower opening ( 18 ) against the bottom of the housing ( 1 ) in the mud collection chamber ( 4 ) is directed. 3. Apparatus according to claim 2, characterized in that on the or in the opening ( 18 ) of the tube piece ( 17 ) a grid-like packing carrier ( 19 ) is arranged. 4. Device according to one of claims 1 to 3, characterized in that the pipe section ( 17 ) is formed from a material which has a more positive normal potential than this for activating the corrosion of the metal particles. 5. Device according to one of claims 1 to 4, characterized in that the housing ( 1 ) is transparent at least in the bottom region up to the level of the opening ( 18 ) of the pipe section ( 17 ). 6. Apparatus according to claim 1, characterized in that the packing ( 3 ) is surrounded on the inflow and outflow sides with a flow-through cover ( 2 ) and the inflow surface of the metal particle packing ( 3 ) corresponds to a multiple of the cross-sectional area of the inflow connection ( 12 ). 7. Apparatus according to claim 6, characterized in that at least the inflow-side cover ( 2 ) is formed from a material which has a more positive normal potential than the metal particles for activating the corrosion of the metal particles or that part of the metal particle packing ( 3 ) is made of ed leren metal particles, such as stainless steel and the other part is made of less noble metal particles and both types of particles are evenly distributed in the package ( 3 ). 8. Apparatus according to claim 6 or 7, characterized in that the metal particle packing ( 3 ) is formed from a ring and the central free space ( 5 ) against the sludge collection chamber ( 4 ) is closed. 9. Device according to one of claims 1 to 8, characterized in that the housing ( 1 ) with a releasable closure cover ( 8 ) and below this in an opening ( 9 ) a partition ( 10 ) between the inflow and outflow chamber ( 6, 7 ) the metal particle pack ( 3 ) with the sludge collecting chamber ( 4 ) in the form of a set is removably arranged. 10. Device according to one of claims 1 to 9, characterized in that the housing ( 1 ) is provided with a sludge drain ( 11 ). 11. Device according to one of claims 1 to 10, characterized in that the inflow and outflow connections ( 12, 13 ) of the Ge housing ( 1, 1 ' ) are provided with closure valves ( 14 ). 12. Device according to one of claims 1 to 8, characterized in that the housing ( 1 ) from a with the inlet and outlet connections ( 12, 13 ) provided upper part ( 1 '' ) and a detachable but tightly connectable, pot-like Lower part ( 1 ' ) is formed. 13. Device according to one of claims 1 to 12, characterized in that the pack ( 3 ) is arranged as a self-contained, flowable body inserted in the device.