HU201142B - Multi-way boiler for cooling aggregates of compensating gas-absorption type - Google Patents

Abstract

In this multi-way boiler, at least two of the heating pipes /3, 4/ which serve for transmitting the heat energy necessary for boiling out the cooling solution and/or for raising the solution are arranged inside the transverse profile of the jacket /1/ of the boiler. The upper and lower ends /16, 17/ of the heating pipes /3, 4/ can either be open or only the lower end of one heating pipe can be open or the fitting can also be designed in such a manner that one heating pipe projects beyond the bottom /18/ which closes the jacket, or that one heating pipe projects beyond both the bottom /18/ and the lid /19/ of the jacket /1/. The lower and/or upper end of the projecting heating pipe can also be designed in a shape which deviates from the cylinder. The cross-section of the individual construction elements, in particular that of the jacket and of the heating pipe, can also be a cross-section deviating from the circle.

Description

BACKGROUND OF THE INVENTION The present invention relates to a multi-path boiler for an expansion cooling system with an expansion tube. having a plurality of sheaths (18) sealed with a bottom (18), a top (19), a heat seal (5) surrounding the sheath (1) and a rich solution extending across the bottom (18) and the cover (19). the pipe (7) and the heating pipes (2, 3, 4) being arranged so that at least one of the heating pipes (2.3, 4) is located outside the heating pipe (2) within the cross section of the jacket (1), another heating pipe (3.4) is located within the cross-section of the jacket (1). (Figure 1)

Scope of the description: 12 pages, figure 6

-1HU 201142 Β

BACKGROUND OF THE INVENTION The present invention relates to a multi-path boiler suitable for an absorption cooling unit with an expansion tube and having a jacket sealed at the bottom, top with a lid, thermal insulation around the jacket, and a rich solution tube passing through the bottom. and has heating pipes.

It is known that the absorption cooling unit, by virtue of its characteristics, is capable of operating the thermal energy required for its operation, e.g. by heating the electric cartridge or by burning fossil fuel to its drive part, the boiler. In one-way designs, heat can be supplied by electric heating or fossil fuel combustion, while in multi-way designs they can be alternatively combined. Multi-boiler refrigeration units thus represent a wider use of heating energy and, by virtue of the possibility of operating from different energy sources, a refrigeration unit operating on this principle also provides higher service and higher comfort.

The three-way absorption cooling unit designed based on the foregoing considerations can be operated, for example, from a 220 V, 50 Hz mains voltage or a 12 V DC or a propane-butane gas bottle. This is especially advantageous for refrigerators built into caravans because the mode of power supply can be selected according to the location of the caravan.

In a known type of three-way boiler, the gas burner is arranged under a heating pipe located inside the boiler jacket, while the mains and / or mains heaters are arranged under the heater. Low Voltage Heating Cartridges are housed in welded heating tubes on the outside of the housing. The jacket and the external heating pipes are surrounded by a thermal insulation. With reference to Fig. 1, a design similar to the one to be described in more detail hereinafter can be found in FR-2,444,524. patent.

The heat transfer between the rich solution and the heating tube can be improved if the heating tube is surrounded by the rich solution tube as a snake. U.S. Pat. No. 3,225,560 discloses such a solution. patent specification.

The known solutions have several disadvantages. One is. that the efficiency of the heat transfer is very low, since heat reaches the solution only through the contact surfaces of the jacket and heating pipes and the weld seams.

A further disadvantage is that the heat transfer surface of the jacket and the heating pipes together is relatively large and thus, despite the thermal insulation, the heat loss is very high.

The disadvantage is also. that heating through the heating pipes has a high surface temperature, so that the heat dissipated through the heat insulation, which cannot be utilized in the process, increases in proportion to the increase in the surface temperature. The part of the heat that goes through the insulation to the environment is completely wasted. The part of the heat that goes out into the cooled space, not towards the environment, means even greater loss because of the as a single loss, the amount of heat entering the chilled space must be subtracted from the cooling unit. This heat dissipation can take place at an efficiency of only about 30-40 9f, so that the amount of heat involved is a multiple loss for the operation of the complete refrigeration unit. Of course, each of these losses has an effect on increasing the energy consumption of the refrigeration unit.

It is an object of the present invention to eliminate or reduce the drawbacks of the prior art and to provide a multi-path boiler for the use of high-efficiency heat recovery cooling equipments. The present invention has led to the discovery that the heat transfer losses can be substantially reduced if the heating pipes for the release of heat energy are located within the cross section of the jacket.

Thus, the invention relates to a multi-path boiling, expansion tube absorption cooling unit having a jacket sealed with a bottom bottom, a top lid, a heat seal surrounding the jacket, and a rich solution tube extending through the bottom and lid, in a manner known per se, at least one heating pipe is disposed within the transverse section of the jacket in addition to a heating pipe disposed within the transverse section of the jacket.

A preferred embodiment of the multi-path boiler of the present invention is that all of its heating pipes are disposed within the transverse section of the jacket.

In another preferred embodiment of the multi-path boiler according to the invention, each heating pipe has an opening through both the bottom and the lid.

A third preferred embodiment of the multi-path boiler of the present invention comprises a heating pipe having one end closed within the jacket from the bottom or lid.

A fourth preferred embodiment of the multi-path boiler according to the invention is such that at least one heating pipe extends over the bottom and / or the lid.

In a fifth preferred embodiment of the multi-path boiler according to the invention, at least one end of at least one heating pipe has a shape other than a cylinder.

Finally, a preferred embodiment of the multi-path boiler according to the invention is one in which the cross-section of the jacket and / or heating pipes is different from that of a circle.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be more fully understood from the comparison of the state of the art and some embodiments with reference to the accompanying drawings, in which:

Figure 1 - Partially sectioned, partly axonometric, a prior art multi-boiler, the

Figures 2 and 3 are a plan view of the multi-path boiler according to the invention in sectional view and "A" in top view,

Figures 4 and 5 - another embodiment, in plan view and in a 3 "section marked on the top view,

Figures 6 and 7 - a third plan view and sectional view "C" of the top view,

Figures 8 and 9 - a fourth embodiment, in sectional view and in sectional view "D" in the top view, and finally

Figures 10 and 11 schematically illustrate a fifth embodiment of the fifth plan view and the sectional view marked "E" on the top view.

For the sake of clarity, first by carrying out a detailed analysis of the known solution of FIG. The mantle 1 is closed at the bottom by the bottom 18 and the lid by the top 19, and the poor solution 6 fills the space left by the rich-data tube 7 and the heating pipe 2.

The rich solution tube 7 contains the rich solution 8 and extends into the pump tube 9.

A gas burner (not shown) is located below the heating pipe 2. The heating pipe 2 opens on the bottom 18 with the through opening 17 and on the lid 19 with the opening 16 outside the multi-path boiler. The gas burner is located below the lower through hole 17.

A heating pipe 3 is provided to the jacket 1 from the outside by the welds 14 and 15. a heating pipe 4 is secured by the welding seams 12 and 13. The heating pipe 3 at the contact surface 10 and the heating pipe 4 at the contacting surface 11 abut against the jacket 1. The contact surfaces 10 and 11 and the weld seams 12, 13, 14 and 15 are thermal bridges.

The heating pipe 3 is fitted with heating cartridges operable from 220 V AC and the heating pipe 4 from 12 V DC.

The jacket 1 and the heating pipes 3 and 4 are surrounded by a thermal insulation 5.

The presently presented apparatus operates in a known manner.

Figures 2 and 3 show the best approach for the prior art design. It should be pointed out here that thermal insulation is no longer specifically mentioned or depicted. Of course, thermal insulation is required, but it does not play a role in understanding the invention.

It is also to be noted that the present invention is illustrated by a multi-path boiler having only two heating pipes. It will be obvious to one skilled in the art that the principle can be applied without any remedy if more than two heating pipes are required.

Referring now to Figures 2 and 3, heating tubes 3 and 4 are located within the cross-section of the jacket 1. The jacket 1 is closed at the top by the lid 19 and the bottom by the bottom 18, on which the heating pipes 3 and 4 open outwardly of the boiler with one of the opening 16 and 17 respectively. The other elements are the same as the prior art solution.

It will be readily appreciated that since the heater tubes 3 and 4 are in contact with the poor solution 6 on their entire outer surface, the heat transfer is significantly better than when the heater tubes 3,4 are outside the jacket 1.

In the embodiment shown in Figures 4 and 5, the upper end of one of the heating pipes 4 is still closed inside the housing 1 so that it does not even touch the lid 19. This has the double benefit. On the one hand, the surface on which the heat cartridge transfers heat to the poor solution 6 increases, and on the other hand, the heat cartridge does not radiate heat to the boiler environment.

Structural conditions may require that the size of one of the heating pipes 3, 4 differ from the size of the jacket 1. The heating pipe 3 shown in Figs. 6 and 7 only extends over the bottom 18 and in Figs.

For gas-fired boilers, it is expedient to fit the shape of the heating pipe 3, 4 to the gas burner. 10 and

Figure 11. wherein the end of the heating pipe 3 extending below the bottom 18 is flushed into a throat 20. The throat is rectangular; cross.

The heating pipes shown in the figures are circular in cross-section, while the jacket shows a polygonal shape. Without further explanation, it is clear that there are no strict rules for the cross-section of either the heating pipe or the jacket, and the most suitable profiles are always used.

Finally, it should be noted that the exemplary embodiments are merely basic variants and can be made up in many combinations.

PATENT CLAIMS

Claims (7)

1. A multi-path boiler for an expansion coolant absorption tube having a jacket sealed at the bottom with a lid, a heat seal surrounding the jacket, and a rich solution pipe extending through the bottom and lid into the cross section of the jacket, , 3, 4), in a manner known per se, at least one heating pipe (3, 4) disposed within the transverse section of the jacket (1) within the transverse section of the jacket (1), A multi-path boiler according to claim 1, characterized in that each heating pipe (2, 3, 4) is disposed within the transverse section of the jacket (1). Multi-path boiler according to claim 1 or 2, characterized in that each heating pipe (2, 3, 4) has an opening (16. 17) extending through both the bottom (18) and the lid (19). Multi-path boiler according to claim 1 or 2, characterized in that it has a heating pipe (4), one end of which is closed from the bottom (18) or the lid (19) within the jacket (1). 5. Multi-path boiler according to any one of claims 1 to 3, characterized in that at least one heating pipe (2, 3, 4) extends over the bottom (18) and / or the lid (19). 6. Multi-path yarn according to any one of claims 1 to 3, characterized in that at least one end of the at least one heating pipe (2, 3, 4) is of a shape other than the cylinder. 7. Multi-path boiler according to one of Claims 1 to 3, characterized in that the cross-section of the jacket (1) and / or the heating pipes (2, 3, 4) is different from the circle. -3HU 201142 Β Figure 1 -4HU 201142 Β 6/2 2. abra -5HU 201142 Β 5/3 4 friends -6HU 201142 Β 6/4 Figure 6 cl -7HU 201142 Β