DE69800161T2 - Radiator for heating system with liquid circulation - Google Patents

Abstract

The radiator section (1), equipped with couplings (10) for tubes linked to another section above it, has connectors (16, 18) for joining it to another radiator section located end to end with it and contains at least two parallel heating fluid distribution channels (2, 4). The channels are linked by compensating chambers (5) at the ends of the section which can be fitted with separators to give a more complex fluid trajectory, while grooves (14) in the section ends are designed to receive seals between adjacent sections.

Description

The invention relates to a modular ramp element according to the preamble of patent claim 1. The invention also relates to a radiator for a heating system with a modular ramp element.

The invention relates to radiators constructed from standardized parts, which at the same time allow the advantage of using a small number of parts. These can be manufactured to a high quality level at a reasonable price and allow the realization of shapes suitable for a practically unlimited number of aesthetic and technical requirements.

The first assembled radiators for domestic use, using standardised elements, were made of cast iron. The technical and mechanical properties of cast iron resulted in very massive and unattractive shapes. In addition to the problems of cavities and corrosion, the temperature irregularities in the volume of the radiators in the plane of the joints often caused sealing problems, as described in particular in EP-A-0 518 843.

The radiators made of deep-drawn sheet steel, described in particular in GB-A-2 082 749, pose the problem that their continuous surfaces are unfavourable to the outflow of air, the problem of noise and, likewise, their behaviour in the face of major temperature fluctuations.

EP-A-0 816 791 proposes a heating radiator consisting of ramp sections made of aluminium, the ramp sections being connected to one another by steel radiating pipes. This radiator does not solve the problems arising from the temperature differences. Due to the Fluctuations in the sections between the different elements disrupt the flow of the heat-transferring fluid.

The heat exchangers formed from interconnected distribution ramp elements are known in particular from patent application EP-A-0 631 101, which is considered to be the closest prior art.

The aim of the invention is to bring radiators onto the market in which the problems of uneven distribution of heat flow are practically avoided.

A further aim of the invention is that even in the presence of such irregularities, the radiator is able to reduce these effects to negligible values.

Another aim of the invention is to design modular radiators which, with a reduced number of basic parts, allow a large number of customization possibilities to be satisfied.

The object of the invention lies in a modular ramp element for a heating radiator with fluid circulation, which is crossed axially by at least one distribution ramp segment, with connecting elements to the heat-radiating pipes and means for connecting to at least one adjacent element, each ramp element consisting of at least two parallel distribution ramp segments, characterized in that these at least two segments are connected to one another by closable compensation chambers.

Preferably, each compensation chamber is formed by joining two cavities of complementary shape and dimensions arranged on the front sides of two adjacent ramp elements.

Advantageously, the sealing elements are arranged between two adjacent elements on the circumference of the two complementary cavities, preferably in a groove running around one of the cavities.

According to an advantageous embodiment, at least one of the sealing elements for limiting the fluid passage between at least two ramp segments has an element suitable for at least partially closing the corresponding compensation chamber.

The means for connecting to an adjacent element generally comprise at least one flange crossed by a longitudinal opening extending in a plane lying between the axes of the distribution ramps at each of the ends of the element and a screw element accessible from the outside with corresponding dimensions.

The screw element has, for example, a head with inner surfaces and a threaded shaft, wherein the opening of one of the flanges of the element has a corresponding thread.

The distribution ramps can have an elliptical or oval shape in cross-section.

Likewise, the invention is based on a radiator for a heating system with a circulating fluid, characterized in that it has:

- at least one modular ramp element as described above,

- the hollow heat-distributing elements connected at their respective ends by appropriate connecting means to the distribution ramp segments connected to the inlet of the radiator and to the distribution ramp segments connected to the outlet of the radiator.

Advantageously, the radiator has two groups of ramp elements arranged in parallel, whereby these and the corresponding radiation pipes form a surface.

The radiator may comprise at least two surfaces arranged such that their respective ramps form an angle with one another, and the end elements of the two adjacent surfaces are connected to one another by angle pieces, the sides of which can cooperate with the front faces of the corresponding end elements.

In one embodiment, the ramps are arranged along a vertical axis.

In this case, the radiating hollow elements advantageously have sufficient mechanical properties to serve as a support for objects to be dried.

According to an advantageous embodiment, the ramp elements have an even number of ramp segments, one group of which is connected to the inlet of the radiator and another group to the outlet of the radiator, sealing means being arranged in compensation chambers which connect the segments connected to these two groups.

Advantageously, the ends of the radiating hollow elements are connected separately to each of these two segment groups in the form of a hair clip (or a "U").

Preferably, the radiator has at least one ramp end piece in a shape that is adapted to that of the front side of one of the ramp elements.

Advantageously, one of the end pieces supports a seat of a thermostatic valve projecting into the interior of the cavity and a closure of the Seat of a thermostatic valve, the control element of this closure being attached to the outside of this end piece.

Further possibilities and advantages of the invention will become apparent from the following description of several specific embodiments with reference to the accompanying drawings.

- Figures 1 and 3 are perspective views of the inventive radiator ramp elements with double and triple ramp segments.

- Figs. 2 and 4 are exploded perspective views of radiators integrating the heads as shown in Fig. 1 and Fig. 3, respectively.

- Fig. 5 is a perspective view of another embodiment of a radiator using the head elements shown in Fig. 1.

Fig. 1 shows a head element of the radiator according to the invention. This extended element 1 consists of two ramp elements 2, 4 arranged in parallel, both of which open with their ends into cavities 5 machined into each end face 6, 8 of the element 1.

Element 1 is made from a single piece of light metal, for example aluminium.

The hollow pins 10 in the form of crowns are aligned parallel on one of the sides of the element 1, whereby the interior of each of these crowns is directly connected to the corresponding ramp segment 2, 4.

The hollow pins 10 form part of a simple device for connecting to the heat radiating elements 12, such as the tubes shown in Fig. 2.

The outer diameter of these hollow pins 10 actually corresponds approximately to the inner diameter of the tubes 12. This allows a connection by inserting them into one another and soldering or gluing.

When assembling a radiator, a seal (not shown) is inserted around the circumference 5 of the end face 6, for example in the groove 14 shown in Fig. 1. When the two complementary end faces 6, 8 of the two adjacent elements 1 are placed together, a hermetically sealed chamber 5, 5, the so-called "compensation chamber", the volume of which corresponds to twice the cavities 5, is formed. This chamber 5, 5 connects the ramp segments 2, 4 of the abutting ramp elements 1 to one another.

The walls of the cavities 5 form a structure in the form of a box, which rigidly connects the ramp segments 2, 4.

A rib (not visible in Fig. 1) with a shape adapted to that of the groove 14 protrudes beyond the front side 8 in such a way that it can be inserted into the groove 14 when the two ramp elements 1 are in contact with one another. This prevents any relative transverse movement of these abutting elements 1.

Each end face 6, 8 has means for connecting to an adjacent element. As shown in Fig. 1, two longitudinal openings 16, 18 allow the insertion of threaded elements, screws or bolts, while connecting the two adjacent ramp elements 1.

One of the openings 16 is provided in a flange 20 which stands on the side surface supporting the hollow pins 10. The other opening 18 opens directly into the front side. The openings on one of the two front sides advantageously have 6 or 8 threads.

As can be seen from Figs. 2 and 4, the head of the threaded elements remains fully accessible even when the radiator is fully assembled.

The gap provided between the two ramp segments 2, 4 enables the insertion of a suitably shaped tool, for example a hexagon wrench, to tighten or loosen the threaded elements.

If necessary, a radiator can be dismantled from the middle to remove or insert a new element 1. With the radiators known in the prior art, this was practically impossible.

The presence of a compensation chamber 5, 5 in the radiator head elements according to the invention allows a division of the flow of the heat transfer medium into parallel rows.

This means that the heat transfer medium is distributed between different surfaces and ramps in Tickelmann loops. The shape of the heads leads to a significant reduction in pressure losses, as the cross-sectional reductions have been reduced to a minimum. The radiator therefore immediately leads to a state of heat transfer that is as close to optimum as possible, without any external influence.

For heat distribution, the elements 1 can have a suitable number of parallel ramp segments. In Figs. 3 and 4, elements with three ramp segments 2, 3, 4 and a radiator constructed with these elements 1 are shown.

The complete density achieved between the elements 1 allows, among other things, a complete freedom from a certain cross-sectional shape, such as a circular shape, which, when using threaded nipples, would force Consequently, one can choose between cross-sections that are better adapted to flow stresses or mechanical requirements (oval cross-section, elliptical cross-section, etc.).

As shown in Fig. 4, the principle of this ramp element can be applied to any number of ramps and the flow of the heat transfer medium is always evenly distributed between the various parallel surfaces 22. It will also be noted that even if a failure occurs due to an external cause, accumulation of residues and particles from the installation, the radiator continues to operate due to the automatic balance of the flows in the structure. The design of the elements 1 limits and the enclosure of the cavities cancels or prevents any relative displacement of the elements 1, a known cause of leakage failures having its origin in the different thermal expansion of the heat radiating tubes 12, particularly when using long tubes.

The presence of the cavities 5 at the head of the elements 1 allows, among other things, several advantageous variations. Angle connectors have been designed in this way, the front surfaces of which fit exactly onto the front surfaces of the two elements 1. This allows the creation of ramps in a zigzag shape, the surfaces of which follow 22 secant surfaces. This always makes it possible, using standardized elements, to create a radiator that runs continuously along the walls of a room, adapting to partition walls, etc.

A further advantage is the accessibility of the cavities 5 forming the compensation chambers. If desired, the bridging that arranges the ramp elements 2, 4 in parallel in an element or a series of elements can be interrupted by means of a dividing tongue 24, the dimensions of which correspond to the cross-section of the compensation chamber 5, 5. If necessary, this tongue 24 can consist of one piece with the sealing profile.

Inserting the tongues 24, which are precisely located in the ramps 2, 4, allows the heat transfer fluid to follow complex paths while optimizing the heat flow by adjusting the pressure losses at each distribution node. It also allows certain ramp segments of the same element 1 to take on different tasks. According to Fig. 5, a first series of ramp segments 2 thus takes on the task of an inlet ramp for the heat transfer fluid, and a second ramp takes on the task of the outlet ramp.

The radiator shown in Fig. 5 contains heat radiating tubes angled in the form of hairpins. This makes certain decorative effects possible. Furthermore, the radiator according to Fig. 5 can be supported only by its ramp. This solves the difficulties caused by thermal expansion caused by elongation of the heat radiating tubes.

The radiator according to Fig. 5, like the radiators shown in Figs. 2 and 4, can be arranged with the vertically or horizontally extending elements 1 without significantly changing their operating behavior. Likewise, taking into account the relevant mechanical requirements, the radiators according to the invention can be used in a bathroom as a clothes dryer or heated towel rail.

The radiators according to the invention constructed with the elements 1 have the advantage of a very large contact surface with the ambient air. This means that they can be constructed very compactly and/or used with a heat-transferring fluid with much lower temperatures than with classic radiators.

Although the heat radiating elements are shown here in the form of circular tubes, it turns out that they can also be provided with wings that promote heat transfer or given any desired shape.

The ramp elements of the radiators according to the invention enable very compact connections. The ramp ends formed by these elements can be connected to end pieces 26 in the form of shells, the size of which does not exceed that of the end faces 6, 8. These end pieces 26 can already have the inlets provided with internal threads, which open optionally to the rear, side or lower end of an assembled radiator and thus make the use of visible connecting pieces superfluous and reduce the visible pipe length to a minimum.

It is also possible to arrange valve seats, such as thermostatic valves, even in the interior of the end pieces 26 in the form of troughs. This means that all protruding elements of the radiator disappear, with the exception of the head of the valve itself.

With careful arrangement of the dividing tongues 24 and the end pieces, the installation of the piping can be equally simplified and the inlet and outlet of the heat transfer fluid can be located at two adjacent points.

Claims (17)

1. Modular ramp element (1) for a heating radiator with fluid circulation, which is crossed axially by at least one distributor ramp segment, with connecting elements (10) to the heat-radiating elements (12) and means (16, 18) for connecting to at least one adjacent element (1, 26), each ramp element (1) consisting of at least two parallel distributor ramp segments (2, 3, 4), characterized in that these at least two segments (2, 3, 4) are connected to one another by closable compensation chambers (5, 5). 2. Modular ramp element (1) according to claim 1, characterized in that each compensation chamber (5, 5) is formed by joining two cavities (5) with a shape and complementary dimensions arranged on the end faces (6, 8) of the two adjacent ramp elements (1). 3. Ramp element (1) according to claim 2, characterized in that sealing elements are arranged between two adjacent elements (1) on the circumference of the two complementary cavities (5). 4. Ramp element (1) according to claim 3, characterized in that the sealing elements are arranged in a groove (14) running around one of the cavities (5). 5. Ramp element (1) according to any one of claims 2 to 4, characterized in that it comprises a removable dividing tongue (24) for at least partially closing the compensation chamber (5, 5) in a manner for limiting the passage of the fluid between at least two ramp segments (2, 3, 4). 6. Element according to any one of the preceding claims, characterized in that the means (16, 18) for connecting to an adjacent element comprise at least one flange (18) crossed by a longitudinal opening (16) extending in a plane lying between the axes of the distribution ramps (2, 3, 4) at each of the ends (6, 8) of the element (1) and a screw element accessible from the outside with corresponding dimensions. 7. Element according to claim 6, characterized in that the screw element has a head with inner surfaces and a threaded shaft, wherein the opening (16, 18) of one of the flanges (20) of the element (1) has a corresponding thread. 8. Element according to any one of the preceding claims, characterized in that the distribution ramp segments (2, 3, 4) have an elliptical or oval shape in section. 9. Radiator for a heating system with a circulating fluid, characterized in that it comprises: - at least one modular ramp element (1) according to any of the preceding claims, - the hollow heat-distributing elements (12) connected at their respective ends by suitable connecting means to a distribution ramp connected to the inlet of the radiator and to a distribution ramp connected to the outlet of the radiator. 10. Radiator according to claim 9, characterized in that it has two groups of ramp elements (1) arranged in parallel and these ramp elements (1) and the corresponding radiation pipes (12) form a surface (22). 11. Radiator according to claim 10, characterized in that it has at least two surfaces (22) and the end elements (1) of two adjacent surfaces are connected to one another by angle pieces, the sides of which can interact with the end faces of the corresponding end elements (1). 12. Radiator according to claim 9, characterized in that the ramp elements have an even number of ramp segments, a group of these segments is connected to the inlet of the radiator, another group of these segments is connected to the outlet of the radiator, and sealing tongues (16) are arranged in the compensation chambers (5, 5) connecting the segments connected in the two groups. 13. Radiator according to claim 12, characterized in that the ends of the radiating elements (12) are connected separately in the form of a U to each of these two segment groups. 14. Radiator according to any one of claims 9 to 13, characterized in that it has at least one end piece (26) in a shape adapted to that of the front face (6, 8) of one of the ramp elements (1). 15. Radiator according to claim 14, characterized in that one of the end pieces (26) supports a seat of a thermostatic valve protruding into the interior of the cavity (5) and a closure of the thermostatic valve cooperating with this seat, the operating element of this closure being fastened to the outside of this end piece (26). 16. Radiator according to any one of claims 9 to 15, characterized in that the ramps are arranged along a vertical axis. 17. Radiator according to claim 16, characterized in that the radiating elements (12) have sufficient mechanical characteristics for supporting objects to be dried.