RU2622452C2 - Plate heat exchanger - Google Patents

Abstract

FIELD: heating system.SUBSTANCE: plate heat exchanger comprises a wafer pack (2) and a covering it case (1). The wafers (2a) are linked in the pack (2) in such a way that the first and at least one other medium flow interchangeably in-between the adjoined wafers. One medium is delivered to the wafer pack (2) or is drained through the leak channel toward wafer pack, while the other medium is delivered to the sufficient spaces in-between the wafers or is drained through the space between the case (1) and the wafer pack (2) on the outside perimeter. It is of the essence that the following materials combination is applied: the wafers (2a) of the pack (2) are made in a known way of a corrosion-resistant material, the body is made of a non-corrosion-resistant material that has an enamel covering on the inside tending to be affected by the medium.EFFECT: heat interchange increase.13 cl, 2 dwg

Description

The invention relates to a plate heat exchanger consisting of a package of plates and a housing enclosing it, the plates being interconnected in the package so that through the gaps between adjacent plates alternately can flow the first medium and at least one other medium, one of which of these media can be fed into or removed from the package of plates through flow channels passing in the direction of the package, while the second medium can be fed into the spaces between the plates or removed from them through omezhutochnoe space between the housing and the plate pack along the outer perimeter.

Such plate heat exchangers are known and have numerous embodiments. The present invention relates to heat exchangers of this design, the plates of which contain seals along their edge and partially around the flow openings and are tightly compressed in the direction of the package. This design has the advantage that the plate package can be opened, inspected and cleaned in a simple way.

However, along with this, the present invention also relates to fully welded plate heat exchangers according to US 6 158 238, US 2005/0039896, WO 2008/046952 and WO 2010/149858, the content of which is to exclude unnecessary repetitions and is the content of this application. Moreover, the package of plates consists of many pairs of plates, and each such pair is formed by two plates welded together, at least along their outer perimeter. Each plate has at least two holes for the flow of one of the media, while adjacent pairs of plates are connected by welding along these holes, as a result of which the aforementioned medium flows through these holes from one pair of plates to another. In contrast, another medium flows through the intermediate space between the housing and the plate stack and flows along the outer perimeter of the plate stack into the spaces between adjacent pairs of plates.

The invention also relates to mixed forms, which are the middle between the two above-mentioned designs of plate heat exchangers, i.e. to partially welded heat exchangers, in which pairs of plates welded to each other are compressed through seals, i.e. only gaps between adjacent pairs of plates can always remain open.

Of course, these plate heat exchangers can also have a configuration in which more than two fluids can be used for heat transfer, or in which the heat transfer spaces between the plates do not immediately follow each other, but form an inactive gap between the plates, which serves, for example, as a safety buffer.

As mentioned above with respect to the fact that the first and at least one other medium alternately flow through adjacent gaps between the plates, this does not mean that directly adjacent gaps are constantly meant; on the contrary, in the immediately adjacent gap there may be a third medium, whether it is stationary or flowing.

As a material for plate heat exchangers, stainless steel alloyed with chromium and nickel is usually used. In addition, it is known to ensure corrosion resistance, for example, against acids, to additionally add molybdenum as an alloying component or to use plates of titanium, nickel and their alloys. True, these materials have the disadvantage that they are very expensive. Therefore, as it became known from WO 2008/046952, the plates and body of the heat exchanger are made of carbon steel with a carbon content of 0.05 to 2.1%, thereby achieving sufficient corrosion resistance for many applications.

The present invention is based on the task of improving the heat exchanger of the type described above so that, on the one hand, excellent corrosion resistance is ensured and, on the other hand, the manufacturing cost is significantly lower than the existing one.

This problem is solved according to the invention as a result of the fact that the following combination of materials is used. The plate plates are made in a manner known per se from corrosion-resistant material, in particular high-quality steel, the casing, on the contrary, is made of a non-corrosion-resistant material, the inner side of which is exposed to the medium, has an enamel coating.

Thanks to this combination of materials, the cost of the housing material is significantly reduced without reducing its corrosion resistance. Therefore, high corrosion resistance is achieved at a lower cost.

In principle, the body of the heat exchanger can be made of almost any material, if only it is stable enough, strong and suitable for applying an enamel coating on it. It is especially advisable to make the body of enameled black sheet.

It is advisable to apply the enamel coating in several layers, which are primer enamel, characterized by good adhesion to the metal material of the body substrate and leveling, and a coating enamel having high chemical resistance, in particular, which is acid resistant.

With respect to the material composition of the enamel coating of at least the topcoat, it is recommended that it comprises more than 50%, preferably more than 60%, SiO ₂ and / or more than 3.5%, preferably more than 4.5%, TiO ₂ and / or above 12%, preferably above 15% Na ₂ O.

It is also recommended that the enamel coating contain at least in its coating layer B₂ABOUT₃, and / or Ka₂O and / or Li₂O and / or MoO₃, and / or MnO and / or ZrO₂, and / or F, preferably in the one-digit percentage range, respectively. It is also recommended to add BaO, and / or CoO, and / or V₂Os, preferably in the ppm range.

The thickness of the enamel coating is from approx. 1 to 3 mm, preferably approx. 2 mm.

For usually welded connecting pipes to the body, the average specialist can take advantage of well-known alternatives, in particular, he can use high-quality steel. Also within the scope of the invention, connecting nozzles can be used, in particular when they are designed for a medium flowing through an intermediate space between the housing and the plate pack made of black tin with enamel coating.

Other features and advantages of the invention follow from the following description of an exemplary embodiment and drawing. This shows:

FIG. 1 is a section through a plate heat exchanger according to the invention, made perpendicular to the plates;

FIG. 2 is a plan view of the outer and inner sides of a pair of plates.

The drawing shows a housing 1, covering in a known manner a package of 2 plates. The housing 1, as well as the package of plates, may have a rectangular, round or other contour.

The package of plates 2 consists of pairs of plates welded between each other 2a, and through each pair of plates a medium flows through at least one connecting pipe 3 at the top of the package of plates and discharged through at least one connecting pipe 4 at the bottom parts of the plate pack. For this, the plates 2a comprise flow openings made in a known manner and arranged coaxially with the connecting pipes 3 and 4.

At least along these flow openings adjacent pairs of plates are welded together, as a result of which flow gaps are formed between all adjacent pairs of plates for another medium. This other medium is supplied through the connecting pipe 5 to the upper perimeter of the package of plates 2, flows down from it along the lower edge and is discharged through the connecting pipe 6. In this case, the elements 1a, which are known per se to be integrated in the housing 1, provide a position in which the medium does not flow last outward around the package of plates, and through the cracks between the pairs of plates.

The described heat exchanger is completely welded and does not contain seals. Depending on the selected flow direction, it can be operated in unidirectional flow mode, against flow or cross flow.

Of significant importance is the fact that the housing 1 is made of a non-corrosion-resistant material and contains on all its internal walls, at least on exposed to the corresponding environment, a coating of technical enamel with a thickness of approx. 2 mm. On the contrary, the package of 2 plates and its connecting pipes 3, 4 consist of corrosion-resistant high-quality steel.

Since it was mentioned above about the inner coating of the housing 1 with enamel, this also applies, of course, to the built-in elements 1a that serve to direct the flow, located not only on the end faces of the package of plates 2, but also along its perimeter.

Regarding the execution of the housing 1, it is recommended that it can open at least from the front side, for which a removable cover should be provided here. It goes without saying that such a cover may also have the above-described enamel coating on the side facing the medium. If, when screwing on the cap, direct contact with opposite enamel coatings can occur, this should preferably be eliminated by laying an elastic seal of a corrosion-resistant polymer.

A particularly optimal composition of the enamel coating, at least for its outer coating layer, can be set as follows:

65% SiO ₂ , 15% Na ₂ O, 5% TiO ₂ , 3.5% ZrO ₂ , 2.5% B ₂ O ₃ ,

1.8% F, 1.7% Li ₂ O, 1.4% MnO, 1.1% MoO ₃ , 1% Ka ₂ O,

0.3% BaO, 0.25% V ₂ 0 ₅ , 0.1% CoO,

while it goes without saying, within the framework of the invention, it is possible to change the above percentage data up or down, respectively, by 5-10% of the original value.

In FIG. 2 shows the possibilities of mating with each other or detachably connecting adjacent pairs of plates and plates of such a pair with each other, the first being shown in the left half of FIG. 2, another view is shown in the right half.

In accordance with the positions of the connecting pipes in FIG. 1, the flow hole for the upper connecting pipe 3 in the plate 2a is indicated by 3a, the flow hole for the lower connecting pipe 4 is indicated by 4a.

According to the top view of the outside of the pair of plates shown on the left, the connection with the adjacent pair of plates — detachable or inseparable — is made along the perimeter of the flow openings 3a and 4a, i.e. in the dark area 13a or 14a. In these sections, which in practice do not mean sections of the perimeter with designated 180 °, but full sections of the perimeter with 360 °, adjacent plates can be joined together by welding.

It is also possible to provide a detachable joint instead of a welding joint, then in the areas shown in black color, of course, a seal will be located throughout the cross section, and the pairs of plates will be compressed externally along the axis, as a result of which adjacent pairs of plates will be located one after another with a seal around the perimeter of holes 3a, 4a.

In both cases, through the gap located outside of the welds or seals 13a, 14a, another medium will flow between the adjacent pairs of plates, supplied or discharged through connecting pipes 5, 6.

In the right half of FIG. 2 shows the connection of two plates of the same pair, namely with an inside view of a pair of plates. Here the plates are welded to each other, respectively, along their outer perimeter or pressed against the intermediate seal with the possibility of separation. This welding or sealing section is indicated by 15, and here it is also to be imagined that the welding or sealing section extends along the entire perimeter, i.e. 360 °.

The flow openings 3a, 4a are open toward the interior of the pair of plates so that the medium can flow from the flow hole 3a through the interior of the pair of plates to the flow hole 4a. The heat exchanger is shown in figures 1 and 2 only schematically, since in this case we are only talking about a special combination of materials, and the flow patterns of the media and the options for welding plates correspond to the prior art.

In summary, it can be noted that the present invention is characterized by the combination of materials with excellent corrosion resistance at a relatively low manufacturing cost.

Claims (14)

1. A plate heat exchanger consisting of a package of plates (2) and a housing (1) enclosing it, moreover, the plates (2a) are interconnected in the package (2) so that the first and at least alternately flow through the gaps between adjacent plates at least one other medium, while one medium is supplied to or removed from the package (2) of plates through flowing channels passing towards the package of plates, while another medium is supplied to or removed from the corresponding spaces between the plates through an intermediate anstvo between the housing (1) and a package (2) of the plates along the outer perimeter, characterized in that the following combination of materials is used: the plates (2a) of the bag (2) are made in a known manner from a corrosion-resistant material, and the casing is made of a non-corrosion-resistant material having an enamel coating on the inside exposed to the environment. 2. The heat exchanger according to claim 1, characterized in that the casing is made of enameled black sheet. 3. The heat exchanger according to claim 1, characterized in that the enamel coating is multilayer. 4. The heat exchanger according to claim 1, characterized in that the enamel coating consists of at least a primer coating and at least a coating coating. 5. The heat exchanger according to claim 1 or 4, characterized in that the enamel coating contains at least in its coating layer more than 50%, preferably more than 60% SiO ₂ . 6. The heat exchanger according to claim 1 or 4, characterized in that the enamel coating contains at least in its coating layer more than 3.5%, preferably more than 4.5% TiO ₂ . 7. The heat exchanger according to claim 1 or 4, characterized in that the enamel coating contains at least 12% in its coating layer, preferably approx. 15% Na ₂ O. 8. The heat exchanger according to claim 1 or 4, characterized in that the enamel coating contains at least in its coating layer B ₂ O ₃ and / or Ka ₂ O and / or Li ₂ O and / or MoO ₃ , and / or MnO, and / or ZrO ₂ , and / or F, preferably in the one-digit percentage range. 9. The heat exchanger according to claim 1 or 4, characterized in that the enamel coating contains, at least in its coating layer, BaO, and / or CoO, and / or V ₂ O _5, preferably in the ppm range. 10. The heat exchanger according to claim 1, characterized in that the thickness of the enamel coating is from approx. 1 to approx. 3 mm, preferably from approx. 1.5 to approx. 2.5 mm. 11. A heat exchanger according to claim 1, characterized in that the housing (1) contains welded-in integrated elements (1a) for directing the flow, which are also made of enameled black sheet. 12. A heat exchanger according to claim 1, characterized in that the housing (1) contains welded connecting pipes (5, 6), which are also made of enameled black sheet. 13. A heat exchanger according to claim 1, characterized in that the housing (1) comprises housing parts (1a, 1b) connected by bolts.

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