KR200495169Y1 - Heat exchanger and its shell - Google Patents

Abstract

The heat exchanger for gas boilers has a tube nest 12 in the form of a spiral. This tube nest is held in place by a base 22 and a cover 24 that wind the outer perimeter of the tube nest 12 and are arranged on opposite sides of the cylindrical casing 20 and clamped together in use. Enclosed in a shell 18 comprising a cylindrical casing 20 . A plurality of studs 50 having ends for clamping the cover 24 in the pedestal extend from the base 22 to the cover 24 outside the cylindrical casing 20 .

Description

HEAT EXCHANGER AND ITS SHELL

The present invention relates to a heat exchanger for gas boilers. The invention is developed in particular with reference to a heat exchanger for gas boilers with a spiral tube nest. In particular, the present invention relates to the shell of such a heat exchanger.

Gas boilers for heating are known, in which the water to be heated passes through a tube nest wound in spiral form. Combustion gases are generated by a gas burner and passed one or more times through the coils of the tube nest, transferring heat to the water passing through the tube nest. If their heat, including latent condensation heat, is transferred to the water, then the fumes are emitted to the outside of the heat exchanger and gas boiler.

The shell containing the tube nest is an important part of the heat exchanger. The shell must be resistant to the high temperatures of the fumes with which the shell comes in contact. Different parts of the shell are subjected to an extremely wide range of temperatures, and therefore special care must be given to the construction of the shell, taking into account the temperature gradients that can cause major stresses during use of the heat exchanger. do. Accordingly, the materials of the shell should be carefully selected for their resistance, durability, workability and economy. The shell should be as economical as possible to keep the cost of the heat exchanger low. The processing operations to be carried out on the shell during manufacture of the shell should once again be limited to the bare essentials in order to keep costs to a minimum. The shell should be easy to fit, especially by non-professionals, and, depending on the size of the heat exchanger, should be easily adaptable to exchangers with tube nests of different sizes.

The present invention aims to disclose a shell for heat exchangers with a spiral tube nest that meets the requirements described above. For this purpose, the invention relates to a heat exchanger having the features indicated in the claims which follow, which form an integral part of the description of the invention.

The shell of the heat exchanger according to the present invention is designed in such a way that it does not use tie-rods to clamp the base and the cover to the two ends of the cylindrical casing surrounding the tube nest. A plurality of studs, preferably made integral with the base, extend from the base of the shell, preferably made of plastic material. The cover is intended to engage directly over the studs. A cylindrical casing is fixed between the base and the cover.

Advantageously, the shell of the heat exchanger of the present invention does not use gaskets. Preferably, a sealant of silicone type is provided on each of the seals, which can withstand the high temperatures of fumes in contact with the seals. Except for the condensation discharge area created by the cavity on the cylindrical casing, the sealant is located in the contact areas between the cylindrical casing and each of the base and cover. Seals in the regions of the mouths of the spiral tubing as well as seals in this release region are provided by specially shaped inserts. The manufacture of this type of shell, in which the seals are produced by means of a silicone sealant, allows for a fast and accurate assembly of the heat exchanger using automatic machines and, therefore, with limited or zero manual intervention. .

Additional features and advantages will become apparent from the detailed description following a number of preferred embodiments of the invention, given by way of non-limiting example only, with reference to the accompanying drawings.
1 is a perspective view of a heat exchanger according to the present invention;
Fig. 2 is a perspective view similar to Fig. 1, rotated by 90[deg.];
Fig. 3 is an enlarged view of details of the clamping of the base and cover of the heat exchanger of Fig. 1;
Fig. 4 is an enlarged cross-sectional view of a detail of the condensate outlet;
5 is an enlarged perspective view of an insert in a shell around a first mouth of a tube nest; And
Fig. 6 is an enlarged perspective view of the insert of the shell around the second mouth of the tube nest;

With reference to the drawings, the number "10" generally denotes a heat exchanger for gas boilers, having a helical tube nest 12 of a known type. 1 , the heat exchanger 10 is shown horizontally for clarity of illustration, but in use, the heat exchanger is arranged to be rotated past 90°, wherein the XX axis of the coils of the tube nest 12 is In a horizontal position, the two mice 14 , 16 of the tube nest 12 face downward.

The tube nest 12 of the heat exchanger 10 is enclosed in a shell 18 . The shell 18 includes a cylindrical casing 20 that winds the outer perimeter of the tube nest 12 . Preferably, the cylindrical casing 20 is made of metal, for example stainless steel. A cylindrical casing 20 is fixed between the base 22 and the cover 24 . The base 22 is preferably made of a plastics material, and the cover 24 is preferably made of aluminum, both of which are produced, for example, by moulding. The cover 24 has a large circular central opening 26 which essentially corresponds to the inner diameter of the tube nest 12 . In use, the boiler's gas burner is positioned next to the circular opening 26 to direct the combustion fumes into the pipe nest 12 . A circular diaphragm 28 is arranged approximately in the middle of the tube nest 12 (see FIG. 2 ). The base 22 communicates with the chamber 30 for collection and discharge of fumes, which exit the shell through an exit aperture 32 .

The cylindrical casing 20 is held in place by the insertion of its two circular end edges in the respective circular grooves 34 , 36 made in the base 22 and in the cover 24 . A sealant, preferably of the silicone type, is disposed in the circular grooves 34 , 36 . The cover 24 has four radially extending extensions 38 . The extensions 38 are reinforced by ribs 40 . In the extensions 38 , a hole 42 is made and nuts 46 housed at the ends 48 of studs 50 extending from the base 22 . and engaging screws 44 are inserted into these holes.

As can be seen in more detail in FIG. 3 , each stud 50 is hollow inside to receive a nut 46 proximate its end 48 . Nut 46 has an abutment surface 52 for supporting end 54 of tapered sleeve 56 that protrudes from extension 38 of cover 24 . Accordingly, the connecting distance between the base 22 and the cover 24 is formed in a precise and predetermined manner. The upper end 48 of the stud 50 is formed by a tapered cavity 58 which places the cover 24 in the center of the base 22 and even consists of the shell 18 . To facilitate assembly of the elements, they mate with the tapered sleeve 56 in a manner that provides a first overall seal between the two elements even in the absence of the screws 44 . The tapered sleeve 56 , preferably made of aluminum, and even more preferably integrally with the cover 24 , is in direct contact with the nut 46 , and thus a self-locking bush. serves as a

The condensate outlet 60 produced on the base 22 is arranged in the region of the heat exchanger opposite the mist outlet 32 . A cavity 62 is created on the cylindrical casing 20 which is intended to convey the condensate to the discharge part 60 , preferably by drawing. Between the base 22 and the cylindrical casing 20, it can be seen more clearly in the enlarged cross-sectional view of FIG. , a molded insert 64 is provided around the condensate outlet 60 . The molded insert 64 serves to create a seal between the base and the cylindrical casing 20 in the region of the condensate outlet, in this region the seal acts as a drainer due to the cavity 62 . Stopped inside A drain cavity 62 serves to facilitate the outflow of the condensate and, since there are no obstacles to the outflow of the condensate, the seating of the sealant seal is internally stopped. Insert 64 serves to restore the seal without impeding condensate outflow.

Additional two molded inserts 66 , 68 , which can be seen more clearly in FIGS. 5 and 6 respectively, are seals of the cylindrical casing 20 around the two mice 14 , 16 of the tube nest 12 . provided to ensure sealing. The molded inserts 64 and 66 are preferably made of a plastics material and are obtained by molding, whereas the insert 68 is preferably made of aluminum. The inserts make it possible to simplify and automate the assembly process of the tube nest 12 and other components of the shell 18 , which is highly beneficial to the seal created by the sealant.

The shell of the heat exchanger described above is readily adaptable for tube nests with different numbers of coils, for making heat exchangers of different sizes. For example, in the case of a heat exchanger where the tube nest has a larger number of coils than illustrated in the figures, the modifications to be made are very simple. This will be necessary to create a cylindrical casing of greater height than the cylindrical casing 20 illustrated in the figures. However, the same base 22 and the same cover 24 seen in the illustrated embodiment can be maintained through the use of distance pieces. The larger spacing between the extensions 38 of the cover 24 and the stud 50 protruding from the base 22 is covered by the use of simple spacing pieces, for example sleeves of suitable length, and this suitable Through the sleeves of length, longer screws than the screws 44 illustrated in the embodiment described above are inserted. Molded inserts 64 , 66 and 68 may also remain unchanged.

Of course, without prejudice to the principles of the present invention, the details of embodiments and implementations may be variously modified from what has been described and illustrated herein without departing thereby from the scope of the present invention.

Claims (17)

A gas boiler encased in a shell 18 having a spiral tube nest 12 and comprising a cylindrical casing 20 wound around the outer periphery of the tube nest 12 . A heat exchanger for the field, comprising:
The cylindrical casing 20 is held in place by a base 22 and a cover 24 arranged on opposite sides of the cylindrical casing 20 and clamped together in use, and a plurality of studs. Studs 50 extend from the base 22 to the cover 24 on the outside of the cylindrical casing 20 , the studs in abutment having ends for clamping the cover 24 . have,
each stud 50 has an end 48 into which a nut 46 is housed;
The ends 48 of the studs 50 are contacting against the cover 24 so that the distance between the base 22 and the cover 24 is reduced by the studs 50 . prescribed,
Heat exchangers for gas boilers. The method of claim 1,
The cylindrical casing (20) is held in place by insertion of the two circular end edges of the cylindrical casing into respective circular grooves (34, 36) made in the base (22) and the cover (24).
Heat exchangers for gas boilers.
3. The method of claim 2,
a sealant is disposed in the circular grooves (34, 36);
Heat exchangers for gas boilers.
3. The method according to claim 1 or 2,
the base (22) communicates with a chamber (30) for collection and discharge of fumes, the chamber being provided with an emitting aperture (32);
Heat exchangers for gas boilers.
3. The method of claim 1 or 2,
the cylindrical casing (20) and cover (24) are made of metal, and the base (22) is made of a plastic material,
Heat exchangers for gas boilers.
6. The method of claim 5,
the studs (50) are made of a plastic material and are integrated with the base (22);
Heat exchangers for gas boilers.
3. The method of claim 1 or 2,
each stud (50) is internally hollow to receive a nut (46) proximate to one of the ends (48) of the stud;
Heat exchangers for gas boilers.
8. The method of claim 7,
The nut 46 has an abutment surface 52 which supports the end 54 of a corresponding sleeve 56 projecting from the cover 24 towards the base 22 . ,
Heat exchangers for gas boilers.
9. The method of claim 8,
the sleeve (56) is tapered and mate with the end (48) of the stud (50), the stud defining a tapered cavity (58);
Heat exchangers for gas boilers.
8. The method of claim 7,
The cover 24 has a plurality of radially extending extensions 38 , and a hole 42 is made in each extension through which a stud extends from the base 22 . a screw 44 is inserted to engage a corresponding nut 46 housed at the end 48 of 50;
Heat exchangers for gas boilers.
3. The method of claim 1 or 2,
There are no gaskets, and the seals are provided by the sealant,
Heat exchangers for gas boilers.
3. The method of claim 1 or 2,
The cylindrical casing 20 has a cavity 62 which serves as a drainer intended to transport the condensate collected inside the shell 18 towards the condensate discharge 60 produced in the base 22 . ) with
Heat exchangers for gas boilers.
13. The method of claim 12,
Between the base (22) and the cylindrical jacket (20), around a cavity (62) serving as a drainer, a molded insert serving as a seal between the base and the cylindrical casing (20) (64) is provided around the condensate discharge (60),
Heat exchangers for gas boilers.
3. The method of claim 1 or 2,
The shell (18) has inserts (64, 66, 68) molded around sealing areas between a cylindrical casing (20) and a base (22) or cover (24).
Heat exchangers for gas boilers.
15. The method of claim 14,
Two or more molded inserts 66 , 68 are attached to the casing to provide sealing of the cylindrical casing 20 around two mouths 14 , 16 of the tube nest 12 , respectively. 18) attached to the base 22 and the cover 24, respectively,
Heat exchangers for gas boilers.
15. The method of claim 14,
The two or more molded inserts 64, 66 are made of a plastic material and obtained by molding,
Heat exchangers for gas boilers.
Encloses a spiral tube nest of a heat exchanger for gas-fired boilers according to claim 1 or 2,
shell.

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