EP2543936A2 - Percolator - Google Patents

Abstract

The instantaneous water heater (1) has an inner tube heating element (2) and an outer jacket tube (3) that are radially spaced apart. The end of the inner tube heating element is sealed. Rib-like projections (6) are arranged around a longitudinal center axis of the inner tube heating element. The rib-like projections are connected to the inner surface of the outer jacket tube to form flow channels connecting an inlet (4) to an outlet (5).

Description

The invention relates to a water heater with an inner tubular heater and an outer thereof radially spaced cladding tube, which is preferably connected at its ends tightly connected to the tubular heater, and having connections for the inlet and outlet of a liquid.

In the prior art water heater of the type mentioned are known.

For example, from the DE 10 2009 024 059 A1 a generic water heater known. In this water heater is provided that the cladding has embossments, which together with the jacket tube surface of the tubular heater form a meandering labyrinth for the liquid between inlet and outlet.

In such a solution, it is disadvantageous that the flow flow of the liquid to be heated is braked by the embossings introduced transversely to the flow direction, and thus a high pressure loss occurs. As a result, a larger-sized pump is required, whereby the total cost of a system with such a water heater increase. In addition, the embossments must be introduced into the cladding tube, resulting in further costs, so that such an overall system causes high costs.

From the DE 10 2009 010 989 A 1 For example, a method and apparatus for generating steam is known. The device for generating steam consists of an elongated heating element that works as a radiant heater, and a surrounding water heater for heating and evaporation of water flowing through with overheating of the steam in the water supply, the steam in the water supply to a temperature above 100 °, is heated in particular over 200 °.

In such a system, in a channel or hose-like geometry, the water is passed around the heating element helically, so that upon heating or overheating of the water, the heat generated in the heating element must first penetrate the wall surrounding the heating element and then the wall of the channel-like water guidance geometry, in order to be heated or to be given to overheated water. This results in energy losses, since the heat to be transferred from the heating element to the water must penetrate an additional wall. In addition, an individual production is required, which is costly.

Due to the above-mentioned prior art, the present invention seeks to provide a water heater of the type mentioned, which is particularly inexpensive to produce, which requires little energy to heat the liquid and low pump power, which also has a long service life having.

To achieve this object, the invention proposes that the tubular heater has on its outer side facing the cladding rib-like projections which form flow channels with the inner shell of the cladding tube, which connect the inlet to the drain.

With such a flow heater, the liquid to be heated flows directly around the jacket of the tubular heater, so that no further wall has to be heated by the tubular heater in order to release the heat energy to the liquid to be heated. The liquid to be heated flows around it on the outside of the tubular heater formed rib-like projections which are heated by heat conduction from the tubular heater and the increase the effective surface area of the tubular heater. Such a water heater with a tubular heater according to the invention is inexpensive and easy to manufacture and has a particularly long service life. In this case, a particularly high proportion of the heat generated by the tubular heater is released to the liquid, so that a high efficiency is achieved. In addition, the rib-like projections form no or only a slight flow obstacle, which has a favorable effect on the required pump capacity for pumping through the liquid.

In particular, it can be particularly preferably provided that the rib-like projections are arranged helically around the longitudinal central axis of the tubular heater running around.

The helical shape of the rib-like projections preferably has a very large pitch with a twist angle of about 20 ° to a length of about 200 mm, which corresponds to a pitch of about 3,600 mm. When used as intended, this causes only slight pressure losses.

If the helical shape has only a slight slope, because the angle of rotation, for example, 360 ° to a length of 5 mm to 20 mm, so this represents a strong loss of pressure flow geometry, which is unfavorable.

Alternatively, it may be particularly preferred that the rib-like projections extend parallel to the longitudinal central axis of the tubular heater. By a parallel along the central longitudinal axis or a preferably around the central longitudinal axis of the tubular heater around helically extending arrangement of the rib-like projections, a particularly high heat input into the liquid to be heated to achieve. The heat transfer to the liquid to be heated is thereby increased by about a factor of 2 or greater compared to other solutions. In addition, occurring through such arranged rib-like projections pressure losses are significantly lower than in other systems with outside circumferential spiral or, for example, meandering cladding.

With the design running parallel to the central longitudinal axis, less heat is transferred to the liquid to be heated than in the coiled version.

In addition, it can be particularly preferably provided that the tubular heater is formed by a heating cartridge with a jacket tube of an extruded profile section with therein arranged helically wire heating wire and the heating wire surrounding insulating, in particular quartz sand.

It can be particularly preferably provided that the extruded profile section of a good heat-conducting material, such as aluminum or steel.

Such a tubular heater with a jacket tube of an extruded section is particularly inexpensive to produce, since only generates a corresponding extruded profile, and then can be cut to length in the desired length. In this case, an extruded profile can first be produced with rib-like projections extending over its length and uniformly distributed over the circumference. This profile or profile sections cut to length can now be rotated about the longitudinal axis so that a helical shape of the projections formed as longitudinal ribs results.

Such a tubular heater has a particularly long service life and is inexpensive and easy to produce.

Furthermore, it can be provided with particular preference that the surface of the tubular heating element around which the liquid flows or can flow around is roughened or ribbed.

This leads to a turbulent boundary layer flow.

The inner shell of the cladding tube can also be roughened or corrugated.

This is an additional improvement of the heat transfer from the lateral surface of the

Tubular heater in the liquid to be heated allows.

It may also be particularly preferred that the rib-like projections bear against the inner shell of the cladding tube.

By the rib-like projections on the one hand and the inner shell of the cladding tube on the other hand, a channel-like guidance of the liquid to be heated is given, wherein the liquid to be heated according to the course of the rib-like projections between the rib-like projections, the outer surface of the tubular heater and the cladding tube is guided and heated.

Alternatively, it can be particularly preferably provided that the rib-like projections are arranged forming a flow gap between the outer edge of the rib-like projection and inner shell of the cladding tube within the cladding tube.

This allows a particularly effective heating of the liquid carried out, because even at the top of the projections heat is released to the medium flowing through and not to the wall of the cladding tube.

In addition, it can be particularly preferably provided that the tubular heating element passes through the cladding tube in a fluid-tight manner on one end face or on both end faces and electrical continuity on the penetrating region Having connecting elements, which protrude from the end face of the tubular heater.

As a result, the tubular heater can be connected in a quick and simple manner with electrical connection means, for example for power supply and / or control, so that, for example, for maintenance or replacement of a tubular heater, this off in a quick and easy way and can be installed again ,

In addition, it can be particularly preferably provided that at least one temperature sensor is arranged on the cladding tube, which protrudes into the gap between the cladding tube and tubular heater.

In particular, it may be particularly preferably provided that within the cladding tube near the inlet, a first temperature sensor and near the drain a second temperature sensor is arranged, which projects in each case into the gap between the cladding tube and tubular heater.

By arranging a first temperature sensor near the inlet and a second temperature sensor near the outlet, a precise monitoring of the heated by the water heater temperature difference of the liquid to be heated is made possible by corresponding evaluation means. In this way, for example, a control unit that evaluates the signals or measured values of the temperature sensor can be signaled to increase the power supply to the heating element to achieve an increase in temperature, or to increase the flow rate or lower accordingly.

For simplified assembly, it may be particularly preferred that the cladding tube is in two parts, for example longitudinally split or transversely divided.

In particular, it may be particularly preferred that the cladding tube consists of two approximately tubular sections, each having at its connection region with the other tubular portion a flange, by means of which the two tubular portions are fluid-tight connected or connected to each other.

The tubular sections formed with a flange can be connected in a simple manner by connecting the flanges quickly and thereby fluid-tight and also separated again, for example, to exchange the tubular heater therein.

Furthermore, it may be particularly preferred that the cladding tube or the tubular sections are made of plastic.

Such a plastic existing cladding can be inexpensive and easy, for example in Plastic injection molding are produced and has a long service life.

It can also be particularly preferably provided that the tubular sections are connected to one another by screwing, clipping, locking, gluing or by plastic welding.

In addition, it can be particularly preferably provided that at least one over-temperature protection fuse is arranged inside the tubular heater.

Finally, it can be particularly preferably provided that the over-temperature protection fuse is formed by a fuse or bi-metal fuse arranged on or near each end face.

The arrangement of an overtemperature protection fuse near each end allows communication with a control unit, for example, a quick shutdown by the control unit at an undesirable excess temperature, in particular to avoid damage to the water heater.

An embodiment of the invention is illustrated in the figures and described in more detail below.

Figur 1

einen erfindungsgemäßen Durchlauferhitzer in Seitenansicht;

Figur 2

desgleichen im Mittellängsschnitt A/A der Figur 1 gesehen;

Figur 3

den Durchlauferhitzer aus Figur 1 und Figur 2 im Querschnitt gesehen;

Figur 4

ein erstes Ausführungsbeispiel eines erfindungsgemäßen Rohrheizkörpers in Seitenansicht;

Figur 5

desgleichen im Längsschnitt A/A der Figur 4 gesehen;

Figur 6

ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Rohrheizkörpers in Seitenansicht;

Figur 7

desgleichen im Mittellängsschnitt gesehen;

Figur 8

einen Rohrheizkörper mit parallel zu seiner Längsachse ausgerichteten Vorsprüngen in Ansicht;

Figur 9

einen Rohrheizkörper in isometrischer Ansicht mit gewendelten rippenartigen Vorsprüngen in Ansicht.

It shows:

FIG. 1

a flow heater according to the invention in side view;

FIG. 2

likewise in the middle longitudinal section A / A of FIG. 1 seen;

FIG. 3

the water heater FIG. 1 and FIG. 2 seen in cross-section;

FIG. 4

a first embodiment of a tubular heater according to the invention in side view;

FIG. 5

likewise in longitudinal section A / A of FIG. 4 seen;

FIG. 6

a further embodiment of a tubular heater according to the invention in side view;

FIG. 7

likewise seen in the central longitudinal section;

FIG. 8

a tubular heater with aligned parallel to its longitudinal axis projections in view;

FIG. 9

a tubular heater in isometric view with coiled rib-like projections in view.

In the FIGS. 1 and 2 a flow heater 1 with a tubular heater 2 and an outer spaced cladding tube 3 is shown. Between tubular heater 2 and cladding tube 3, a flow gap for the flowing through, to be heated medium is formed. The cladding tube 3 is penetrated at its front ends tightly from the tubular heater 2. The cladding tube 3 has connections 4,5 for the inlet (at 4) and the outlet (at 5) of a liquid.

According to the invention, the tubular body 2 has rib-like projections 6 on its outer side facing the jacket tube 3, which form flow channels with the inner jacket of the jacket tube 3. The rib-like projections 6 extend continuously over almost the entire length of the tubular heater 2 and end shortly before the terminals 4.5. The flow channels connect the inlet (port 4) with the drain (port 5). In such a flow heater 1 according to the invention, the liquid to be heated flows around the jacket of the tubular heater 2 and its rib-like projections 6 directly, so that an excellent heat transfer to the liquid flowing through arises. Thus, such a tubular heater 2 has a particularly high degree of efficiency and is also inexpensive and easy to manufacture and has a long service life.

In one in the FIGS. 4 and 5 embodiment shown, the rib-like projections 6 are arranged helically around the longitudinal center axis of the tubular heater 2 extending around. As a result, a particularly efficient heat transfer from the tubular heater 2 is achieved in the liquid to be heated, wherein the liquid is circulated quasi turbulent in the boundary layer.

In one embodiment, which in the FIGS. 6 and 7 is shown, the rib-like projections 6 are arranged to extend parallel to the longitudinal central axis of the tubular heater.

The tubular heater 2 is formed from a heating cartridge with a jacket tube of an extruded profile section with heating wire 7 arranged therein in the manner of a helix and the insulating wire surrounding the heating wire 7, in the form of quartz sand 8 in the exemplary embodiment. The extruded profile section consists of a good heat-conducting material, such as aluminum or steel. Such a tubular heater 2 is inexpensive and easy to manufacture and has a very long service life.

The surface of the tubular heating element 2 that flows around or can be flowed around by the liquid can be roughened or ribbed in order to allow a particularly high heat transfer into the liquid to be heated.

The rib-like projections 6 can either be arranged on the inner jacket of the cladding tube 3 or preferably a flow gap between the outer peripheral edge of the rib-like projection 6 and the inner jacket of the cladding tube 3 forming within the cladding tube 3.

The tubular heating element 2 passes through the cladding tube 3 in a fluid-tight manner on both end faces, wherein electrical connection elements 9 are arranged on the outer regions and protrude out of the tubular heating element 2 on the front side and can thus be connected in a simple manner to corresponding connection means, for example to a control unit and / or a current source are.

In FIG. 2 It can be seen that a first temperature sensor 10 and close to the outlet 5, a second temperature sensor 11 is disposed within the cladding tube 3 near the inlet 4, each temperature sensor 10,11 respectively projects into the gap between the cladding tube 3 and 2 tubular heater to those there existing temperatures of the liquid to measure. The measurement signals are transmitted via line connections to corresponding evaluation means such as an electrical or electronic control unit, by means of which the power of the tubular heater 2 and / or the pump power of a liquid transport pump is controlled.

In the embodiment, the cladding tube 3 is in two parts, namely transversely divided formed. Alternatively, the cladding tube 3 may be formed longitudinally divided.

The cladding tube 3 in the embodiment consists of two approximately tubular sections, each having a flange 12, 13 at its connection region with the other tubular portion. The tubular sections are connected to one another at their flanges 12,13 fluid-tight manner or connected (see FIG. 1 and 2 ) and consist in the embodiment of plastic. Such tubular sections are inexpensive and easy to produce, for example by means of plastic injection molding and thereby have a long service life.

In the exemplary embodiment, the tubular sections are screwed together in the region of their flanges 12,13. Alternatively, the tubular sections can also be connected to each other by clipping, locking, gluing or by plastic welding.

To avoid an inadmissible excess temperature, an overtemperature protection fuse 14 is arranged within the tubular heater 2 in the exemplary embodiment near each end face. The overtemperature protection fuse 14 can be formed for example by a fuse or a bi-metal fuse.

The invention is not limited to the embodiment, but in the context of the disclosure often variable.

All new, disclosed in the description and / or drawing single and combination features are considered essential to the invention.

Claims (18)

Instantaneous water heater (1) having an inner tubular heater (2) and an outer thereof radially spaced cladding tube (3), which is preferably connected at its ends sealed to the tubular heater (2), and the connections (4,5) for the supply and Expiration of a liquid,
characterized in that the tubular heater (2) on its the cladding tube (3) facing the outside rib-like projections (6) which form with the inner shell of the cladding tube (3) flow channels connecting the inlet (4) with the outlet (5) , Device according to claim 1,
characterized in that the rib-like projections (6) helically around the longitudinal center axis of the tubular heater (2) are arranged to extend around. Device according to claim 1,
characterized in that the rib-like projections (6) extend parallel to the longitudinal center axis of the tubular heater (2). Device according to one of claims 1 to 3, characterized in that the tubular heater (2) by a heating cartridge with a jacket tube of an extruded profile section with therein helically arranged heating wire (7) and the Heating wire (7) surrounded insulating, in particular quartz sand (8) is formed. Device according to claim 4,
characterized in that the extruded profile section consists of a good heat-conducting material, such as aluminum or steel. Device according to one of claims 1 to 5, characterized in that the liquid flow around or umströmbare the surface of the tubular heater (2) is roughened or fluted. Device according to one of claims 1 to 6, characterized in that the liquid flow around or umströmbare inner surface of the cladding tube (3) is roughened or serrated. Device according to one of claims 1 to 7, characterized in that the rib-like projections (6) abut against the inner shell of the cladding tube (3). Device according to one of claims 1 to 7, characterized in that the rib-like projections (6) forming a flow gap between the outer edge of the rib-like projection (6) and inner shell of the cladding tube (3) within the cladding tube (3) are arranged. Device according to one of claims 1 to 9, characterized in that the tubular heating element (2) passes through the jacket tube (3) in a fluid-tight manner on one end face or on both end faces and has electrical connection elements (9) at the area which penetrates the front side of the tubular heating element (2 protrude). Device according to one of claims 1 to 10, characterized in that the cladding tube (3) at least one temperature sensor is arranged, which projects into the gap between the cladding tube (3) and tubular heater (2). Device according to claim 10,
characterized in that within the cladding tube (3) near the inlet (4) a first temperature sensor (10) and near the outlet (5) a second temperature sensor (11) is arranged, each in the gap between the cladding tube (3) and tubular heater (2) protrudes. Device according to one of claims 1 to 12, characterized in that the cladding tube (3) is in two parts, for example, longitudinally divided or transversely divided formed. Device according to one of claims 1 to 13, characterized in that the cladding tube (3) consists of two approximately tubular sections, each at its connection region with the another tubular portion having a flange (12,13), by means of which the two tubular portions are fluid-tight connected or connected to each other. Device according to one of claims 1 to 14, characterized in that the cladding tube (3) or the tubular portions made of plastic. Device according to one of claims 13 to 15, characterized in that the tubular sections or the sections are non-positively, positively or materially connected to each other, for example, by screwing, clipping, locking, gluing or by plastic welding are connected together. Device according to one of claims 1 to 16, characterized in that within the tubular heater (2) at least one over-temperature protection fuse (14) is arranged. Device according to claim 17,
characterized in that the excess temperature protection fuse is formed by a arranged at or near each end fuse or bi-metal fuse.

Images