BR202014016933U2 - general liquid combustion immersion heater - Google Patents

Abstract

general liquid combustion immersion heater, the present utility model is described as a general liquid combustion immersion heater which, according to its characteristics, provides the formation of an immersion heater (1) in proprietary, watertight type structure designed to immersion heat a wide range of liquid media by heat dissipation from its structure to the liquid medium - immersion heat dissipation to provide extremely practical, safe and accurate complete optimization in these heating procedures of liquid media contained in reservoirs through the perfect heat exchange between the immersion heater (1) and the immersed liquid medium, combined with low costs and high performance, quality and economy and, based on, an immersion heater (1) with great strength, safety and versatility.

Description

"COMBUSTION IMMERSION HEATER FOR GENERAL LIQUIDS" 001 This utility model is intended for general heaters, more specifically a general liquid combustion immersion heater which, according to its general characteristics, has the following characteristics: The basic principle is to provide the formation of a proprietary and specific watertight immersion heater designed to immersion heat a wide range of liquid media by dissipating heat from its structure to the liquid medium - immersion heat dissipation with a view to to make it extremely practical, safe and precise to fully optimize these heating procedures of liquid media contained in reservoirs through the perfect heat exchange between the immersion heater and immersed liquid medium, coupled with low costs and high performance, high quality. and economy and based on a high strength immersion heater, safety and versatility. With specific design and format and easy access for better adaptation and safety of users, practicality of handling and functionality, very affordable and. Due to its general characteristics and dimensions, it is easily adaptable to a wide range of liquid media, reservoirs, sites and users in general, regardless of the characteristics they may present. 002 Currently, it has become essential for users who need to heat liquid media stored in reservoirs in general, the structuring of a versatile, practical, safe, accurate and efficient structure capable of optimizing the heating of reservoirs of liquid media in general, primarily reservoirs. larger ones containing water such as swimming pools and the like. In a broad analysis of the literature in order to establish the state of the art in relation to liquid media immersion heaters, object of the present utility model, some prior art documents relating to the specific object claimed have been disclosed. in the present utility model, ie. heater intended for immersion heating of liquid media by immersion heat dissipation, such as utility model MU 8001698-7 "Combustion Immersion Heater for Liquids in General" of July 28, 2000, but all based on structure, totally different application and operation of the present utility model, primarily in the range of optimization and performance. 004 Thus, the overall design of the present general liquid combustion immersion heater, object of the present utility model, is based entirely on its simple and robust design with a minimum of components and extremely simplified, safe and optimized operation, combined with very practical manufacturing and maintenance procedures, in order to generate a practical and efficient immersion heater capable of generating through its watertight structure partially immersed in any liquid medium contained in a reservoir and having in its lower part a burner. combustion, a large amount of heat, which will be perfectly dissipated to the medium in which it is immersed by the contact of the immersion heater body with this medium without heat loss. More specifically, this process of heating the liquid medium contained in a reservoir is based on the heat dissipation by immersion, that is, the perfect heat exchange between the immersion heater and liquid media, which is carried out by the heating of the immersion heater (heat generation) and the consequent dissipation of this heat generated internally to the medium in which it is immersed (liquid). The utility model in question is characterized by bringing together components and processes in a different design, which will meet the various requirements that the nature of the use demands, ie. heating of liquids in general through heat dissipation by their structure. This design guarantees a high efficiency immersion heater, functionality, strength, durability, safety, versatility, precision, economy and ergonomics due to the excellent aggregate technical qualities, which provides advantages and improvements in the liquid heating procedures contained in reservoirs. in general and whose general characteristics differ from other forms and models of immersion heaters widely known by the current state of the art. 007 The present utility model consists of the use of a modern, efficient, safe and functional liquid combustion immersion heater in general formed by a set of correctly incorporated physicochemical solutions, composing a unique and complete unique design immersion heater. , details of excellent workmanship, beautiful aesthetic appearance and its own characteristics, which incorporate its own specific and watertight type structure, of high durability and resistance, ellipsoid overall shape and containing perfectly integrated and symmetrically arranged fairing as a protection and finishing element of the immersion heater, a heat exchanger as a heating element for the liquid to which it is immersed, and a support as an immersion heater fixing element near the edge of the reservoir, to enable the formation of a single complete assembly and safe, whose internal and external forms and They allow perfect adaptation to the most diverse types of reservoirs in general, being specially designed for these purposes with their own geometry. The present immersion heater is based on the application of components and processes in a different design without, however, achieving a high degree of sophistication and complexity, making it possible to solve some of the main drawbacks of other shapes and models known by the current state. technology and employed in the heating of liquids contained in reservoirs by immersion heat dissipation - heat exchange between media, which are in a working range in which difficulties of use and application, low efficiency and performance and accidents are very frequent and the shapes and / or models or are based on simple adaptations, thus being of high insecurity, great deterioration and fragility, low durability and resistance, low versatility, high imprecision, laborious application, high losses, no ergonomics, low performance and derisory performance, or are large, being of very high cost, high overall volume and weight, little flexibility, complex handling, high maintenance, great waste of time, complex manufacturing and poor performance. 009 The objectives, advantages and other important features of the utility model under consideration may be more readily understood when read in conjunction with the accompanying figures, in which: 0010 Figure 1.1 is a front perspective view of the combustion immersion heater for liquids in general. Figure 1.2 is a rear perspective view of the general liquid combustion immersion heater. Figure 1.3 is a front view of the general liquid combustion immersion heater. Figure 1.4 is a rear view of the general liquid combustion immersion heater. Figure 1.5 is a side view of the general liquid combustion immersion heater. Figure 1.6 is a top view of the general liquid combustion immersion heater. Figure 2.1 is a perspective view of the general liquid combustion immersion heater in transparency - demonstrating its internal components. Figure 2.2 represents an exploded perspective view of the general liquid combustion immersion heater - demonstrating its main components. 0018 Figure 2.3 is an exploded perspective view of the general liquid combustion immersion heater - demonstrating all of its components 0019 Figure 3 is a perspective view of the heat exchanger of the general liquid combustion immersion heater. Fig. 4 is a perspective view of the heat exchanger of the combustion immersion heater for liquids in general - demonstrating in detail the cold-hot air flow in its lower part. As can be seen from the attached figures illustrating and integrating this descriptive report of the utility model of "Combustion Immersion Heater for Liquids in General", in Figure (1.1) it is presented generally, comprising a full immersion heater (1) with its own characteristics, incorporating its own specific watertight and durable structure, high durability and general shape, ellipsoid shape, internal and external shapes and arrangements to suit various types of reservoirs in general and having perfectly integrated and symmetrically disposed together a fairing (2) of general shape similar to an inverted "L" of elliptical cross-section and arranged vertically and symmetrically along the entire external extent of the immersion heater (1); a heat exchanger (3) of general shape similar to a "L" of rectangular cross-section and arranged vertically, parallel and symmetrically along the entire inner length of the fairing (2) and spaced from the inner faces thereof; and a generally shaped support (4) similar to an inverted "L" and arranged vertically, parallel and symmetrically centered on the postero-upper end of the heat exchanger (3). The fairing (2) consists of an opening (2A) of general semi-elliptical shape and arranged horizontally, parallel and symmetrically along the underside of the fairing (2); a semielipsoidal general shaped opening (2B) arranged vertically, parallel and symmetrically along the rear face of the fairing (2): a chamfer (2C) of ellipsoidal general shape and symmetrically arranged along the upper face of the fairing (2) ) from the posterior to the anterior end: a general shaped (2D) cast resembling an inverted "L" of elliptical cross section and arranged vertically and symmetrically along the entire inner fairing (2) from the openings (2A) and (2B); an opening (2E) of general rectangular shape and arranged vertically, parallel and symmetrically centered on the posterosuperior end of the fairing (2); two openings (2F) of general rectangular shape and each arranged vertically, parallel and symmetrically aligned at one super-lateral end and adjacent the opening (2B); a set of openings (2G) of general rectangular shapes and arranged vertically and symmetrically spaced from each other along the adjacent anterior-inferior and lateral sides of the fairing (2); a generally elliptically shaped opening (2H) arranged parallel and symmetrically over the entire length of the upper fairing face (2); a lid (21) of general elliptical shape and arranged parallel and symmetrically over the entire length of the opening (2H); an opening (2J) of general rectangular shape and arranged horizontally, parallel and symmetrically transverse over the upper-posterior end of the lid (21); and an overcap (2K) of general parallelepipedal shape and arranged horizontally and symmetrically aligned over and along the entire length of the aperture (2J). The heat exchanger (3) consists of an opening (3A) of general rectangular shape and arranged horizontally and symmetrically along the entire length of the upper face of the heat exchanger upper block (3), with the primary function of air inlet and exhaust gas from the flare: a hollow (3B) of general shape similar to a "L" of rectangular cross-section symmetrically arranged along the inside of the heat exchanger (3) from the opening ( 3A), with the primary function of conditioning the heat exchanger components (3); two openings (3C) of general rectangular shape and arranged vertically, parallel and symmetrically centered and along the side faces of the heat exchanger upper block (3), from the opening (3A) to the central alignment of the heat exchanger base (3) with the primary function of water flow - cold water enters hot water; a laterally hollow parallelepipedal shape (3D) partition, arranged vertically, parallel and symmetrically between and along the full length of the two openings (3C) and centered along the inside of the heat exchanger upper block (3) with the gap between the lower end of the partition (3D) and the upper end of the heat exchanger base (3), and having two parallel parallelepipedal and horizontally arranged crosspieces (parallel and symmetrically along the upper and lower ends of the heat exchanger). (3D), and a generally parallelepipedal-shaped hollow (3F) arranged vertically, parallel and symmetrically along the interior of the partition (3D) from one side to the other and interconnecting the openings (3C) of Thus, the partition (3D) symmetrically divides aperture (3A) into an anterior opening (3G) of general rectangular shape and arranged horizontally and symmetrically along the entire length of the superanim ends. of the partition (3D) and the upper block of the heat exchanger (3), and a rear opening (3H) of general rectangular shape and arranged horizontally and symmetrically between and along the full length of the upper-posterior edges of the partition ( 3D) and of the upper block of the heat exchanger (3), as well as structure a front chamber (A) of general parallelepipedal shape and arranged vertically, parallel and symmetrically between the anterior-anterior sides of the heat exchanger (3) and the partition (3D) and a posterior chamber (B) of general parallelepipedal shape and arranged vertically, parallel and symmetrically between the anterior-posterior faces of the partition (3D) and the heat exchanger (3), with the primary functions of anterior chamber formation. (A) and later (B) and water passage - cold water enters hot water: a deflector (31) of general shape similar to an inverted "L" and arranged vertically and symmetrically centered over and along the entire length of the extreme posterior part of the partition (3D) directed to the rear of the heat exchanger (3), with the primary function of directing cold air into the interior of the posterior chamber (B); a gas burner (3J) arranged vertically and symmetrically on the inside of the heat exchanger base (3), with the primary function of burning the gas and heating cold air that enters the rear chamber (B) and exits the anterior chamber (THE); a heatsink (3K) of general shape similar to an inverted "U" arranged vertically, parallel and symmetrically fitted over and along the full length of the anterosuperior end of the heat exchanger upper block (3) and having a set of front ducts (3L) of general parallelepipedal shapes hollow throughout and arranged vertically, parallel and symmetrically aligned laterally along the front of the heat sink (3K) and the front face of the heat exchanger (3 ), a set of general parallelepipedal-shaped posterior ducts (3M) hollow throughout and arranged vertically, parallel and symmetrically aligned laterally along the back of the heatsink (3K) and inside the anterior chamber (B ) of the heat exchanger (3), and a set of openings (3N) of general circular shapes and arranged vertically, parallel and symmetrically spaced along the entire length of the part. anteroinferior of the anterior ducts (3L), with the primary function of heating cold water passing through its anterior ducts (3L) through the heated air in its posterior ducts (3M); a set of pairs of openings (30) of general circular shape and arranged vertically and symmetrically spaced and diagonally aligned along the side faces of the heat exchanger (3) in the alignment of the anterior chamber (A) of the heat exchanger (3) ; a set of ducts (3P) of cylindrical general shapes and each symmetrically arranged between a pair of openings (30) and passing through the front chamber (A) of the heat exchanger (3), with the primary function of heating the cold water which it runs the length of its structure; a gas control valve (3Q) disposed on the outside of the fairing (2) and symmetrically interconnected to the gas burner (3J) through gas ducts and electrical wiring (3R) arranged symmetrically along the full length of the rear chamber ( B) and from the base of the heat exchanger (3), from the control valve (3Q) to the gas burner (3J), with the primary function of starting and feeding the gas burner (3J); a generally trapezoidal shaped chimney (3S) arranged vertically and symmetrically over the full length of the front opening (3G) and the upper ends of the rear duct assembly (3M) and over the full length of the opening (2J) of the lid (21 ), with the primary function of safely driving the firing gases out of the immersion heater (1). 0024 The combustion immersion heater for liquids generally has its operation based on its correct positioning immersed in a liquid medium. The immersion heater (1) must be partially immersed in a liquid medium before being switched on and supported by the support (4) on a solid surface such as the edge of a reservoir, preventing it from sinking into the liquid medium. or keep moving. Properly positioned, the immersion heater (1) will operate from the actuation of the control valve (3Q) which through the power supply and oxidizing element - gas enables the ignition of the gas burner (3J), and this Power and oxidising element-gas conduction is carried out through gas ducts and electrical wiring (3R) disposed along the inside of the rear chamber (B). When the gas burner (3J) is turned on, heat generation begins inside the heat exchanger (3), specifically at the base of it - heating (heat production) and heat dissipation to the environment in which it is located. As heat increases it dissipates through the heat exchanger frame (3) into the medium it is in due to the contact of the heat exchanger frame (3) with the medium in which it is immersed. As the heat dissipation increases, the liquid medium in which the immersion heater (1) is found will be heated to the temperature desired by the user. At the same time as the immersion heater (1) dissipates heat, it also releases flaring gases released by the combustion of the oxidizing elements in the gas burner (3J). These gases are led by chamber (A) and chimney (3S). bypassing the anterior aperture (3G) and aperture (2J) to the external environment. More specifically, the cold air, directed by the deflector (31). It enters the heat exchanger interior (3) through the rear opening (3H) and follows the entire length of the rear chamber (B) until it reaches the heat generated by the gas burner (3J) at its base. When cold air meets this heat it is heated and turned into hot air. This warm air travels the length of the anterior chamber (A), passes through the rear duct assembly (3M) and the anterior opening (3G) until it reaches the chimney (3S) and is released into the room by the opening (3J). . Hot air, circulating through the interior of the front chamber (A) and the rear duct assembly (3M), heats the main structures of the heat exchanger and consequently heats the liquid medium in which the immersion heater is immersed ( 1) by dissipating heat from its structure to the liquid medium - immersion heat dissipation. Cold water, which flows through the heat exchanger (3) through the interior of the partition (3D), anterior duct assembly (3L) and duct assembly (3P), in addition to the direct contact with the heat exchanger structures (3 ), ends up heating by heat dissipation to the liquid medium - heat dissipation by immersion. 0030 The liquid combustion immersion heater is primarily designed to be structured and used with a gas burner (3J) as a heating element for circulating air and water in keeping with the structure of the heat exchanger. (3), however any other type of burner utilizing any kind of oxidizing element may be applied directly to the heat exchanger (3) without any significant changes in its overall structure, ie maintaining all the inherent characteristics of the heat exchanger. immersion (1). The combustion immersion heater for liquids in general, having its components fully integrated with each other and one of the reservoir edges, assembles and disassembles quickly, nothing detaches and nothing has to break or bend, reaches It has a high rate of performance and efficiency, combined with high durability and absolute safety. Once fully integrated with each other and at one of the reservoir edges, the components become clamped and cohesive, thus preventing them from coming loose when in use, making the assembly fully available for liquid heating procedures contained within reservoirs through heat dissipation between the parts. In this way, the immersion heater (1) can be used without any concern whatsoever, especially regarding the durability and safety of its components and the safety of its users in general. 0032 The combustion immersion heater for liquids in general has the specific advantages of having a more efficient heat exchange, which enables energy saving and faster desired result: no need for hydraulic installations beforehand, which allows ease of use and economics; easily placed and / or removed from the means to be heated, allowing its use by any location and any user with ease; and does not require highly skilled labor, which facilitates both its use and its installation. For all of the above it is a heater that will be well received by users of general liquid reservoirs, especially swimming pools and the like, as the combustion immersion heater for liquids in general has numerous advantages such as: great safety , reliability and agility in the application; great performance and performance in its application due to its general conception; high comfort, convenience and safety to users; very high strength and overall durability, coupled with low or no overall wear and tear; fully affordable costs for optimum value for money; practical and safe use by any user; wide range; very low and practical general maintenance; perfect and direct adaptation to the most diverse types of liquids and reservoirs in general; high operational accuracy; great mobility and flexibility of the assembly; fully compatible weight and overall dimensions; large heating capacity; based on ecologically correct concepts; and the certainty of having an immersion heater (1) that fully complies with current laws and regulations and the basic conditions necessary for their application such as safety, precision and performance. All these attributes make it possible to classify the general liquid combustion immersion heater as a totally versatile, efficient, practical and safe means for heat dissipation heating of a wide range of general liquids contained within a wide range of types. reservoirs in general, by the most diverse users and in the most diverse locations, regardless of the general characteristics that they may present, being still of great ease of application and handling, combined with the great performance and excellent general characteristics; however measurements, dimensions and quantities may vary according to the general needs of each application.

CLAIM

Claims (2)

l.) "GENERAL LIQUID combustion immersion heater", characterized in that it is comprised of an immersion heater (1) which incorporates its own specific, ellipsoid-shaped watertight type structure, containing integrated and symmetrically arranged between itself a fairing (2) of general shape similar to an inverted "L" of elliptical cross section and arranged vertically and symmetrically along the entire external extent of the immersion heater (1); a heat exchanger (3) of general shape similar to a "L" of rectangular cross-section and arranged vertically, parallel and symmetrically along the entire inner length of the fairing (2) and spaced from the inner faces thereof; and a generally shaped support (4) similar to an inverted "L" and arranged vertically, parallel and symmetrically centered at the postero-upper end of the heat exchanger (3); wherein the fairing (2) consists of a generally semi-elliptical opening (2A) arranged horizontally, parallel and symmetrically along the underside of the fairing (2); a semielipsoidal general shaped opening (2B) arranged vertically, parallel and symmetrically along the rear face of the fairing (2): a chamfer (2C) of ellipsoidal general shape and symmetrically arranged along the upper face of the fairing (2) ) from the posterior to the anterior extremity; a hollow (2D) of general shape similar to an inverted "L" of elliptical cross section and arranged vertically and symmetrically along the entire inner length of the fairing (2) from the openings (2A) and (2B); an opening (2Ε) of general rectangular shape and arranged vertically, parallel and symmetrically centered on the posterosuperior end of the fairing (2); two openings (2F) of rectangular general shape and each arranged vertically, parallel and symmetrically aligned at one super-lateral end and adjacent to the opening (2B): a set of rectangular and symmetrically spaced rectangular general shaped openings (2G) each other along the adjacent anterior-inferior and lateral sides of the fairing (2); a generally elliptically shaped opening (2H) arranged parallel and symmetrically over the entire length of the upper fairing face (2); a lid (21) of general elliptical shape and arranged parallel and symmetrically over the entire length of the opening (2H); an opening (2J) of general rectangular shape and arranged horizontally, parallel and symmetrically transverse over the upper-posterior end of the lid (21); and an overcap (2K) of general parallelepipedal shape and arranged horizontally and symmetrically aligned over and along the entire length of the aperture (2J); and the heat exchanger (3) consists of a generally rectangular shaped opening (3A) horizontally and symmetrically arranged along the entire length of the upper face of the heat exchanger upper block (3); a hollow (3B) of general shape similar to an "L" of rectangular cross section and symmetrically disposed throughout the interior of the heat exchanger (3) from opening (3A); two openings (3C) of general rectangular shape and arranged vertically, parallel and symmetrically centered and along the side faces of the heat exchanger upper block (3), from the opening (3A) to the central alignment of the heat exchanger base (3); a laterally hollow parallelepipedal shape (3D) partition arranged vertically, parallel and symmetrically between and along the full length of the two openings (3C) and centered along the inside of the upper block of the heat exchanger (3) with the gap between the lower end of the partition (3D) and the upper end of the heat exchanger base (3), and having two parallel parallelepipedal and horizontally arranged crosspieces (parallel and symmetrically along the upper and lower ends of the heat exchanger). partition (3D), and a hollow (3F) of general parallelepipedal shape and arranged vertically, parallel and symmetrically all the way inside the partition (3D). from one side face to another and the openings (3C) interconnected, so that the partition (3D) symmetrically divides the aperture (3A) into an anterior opening (3G) of general rectangular shape and arranged horizontally and symmetrically along the whole. the extension of the super-anterior ends of the partition (3D) and the upper block of the heat exchanger (3), and a rear opening (3H) of general rectangular shape arranged horizontally and symmetrically between and along the entire length of the ends. superimposter of the partition (3D) and the upper block of the heat exchanger (3), as well as structure an anterior chamber (A) of general parallelepipedal shape and arranged vertically, parallel and symmetrically between the anterior-anterior faces of the heat exchanger (3) and the partition (3D) and a posterior chamber (B) of general parallelepipedal shape and arranged vertically, parallel and symmetrically between the anterior-posterior faces of the partition (3D) and the heat exchanger (3); a deflector (31) of general shape similar to an inverted "L" and arranged vertically and symmetrically centered over and along the full length of the rear end of the partition (3D) directed towards the rear of the heat exchanger (3); a gas burner (3J) arranged vertically and symmetrically on the inside of the heat exchanger base (3); a heatsink (3K) of general shape similar to an inverted "ü" arranged vertically, parallel and symmetrically fitted over and along the full length of the anterosuperior end of the heat exchanger upper block (3) and having a set of front ducts (3L) of general parallelepipedal shapes hollow throughout and arranged vertically, parallel and symmetrically aligned laterally along the front of the heat sink (3K) and the front face of the heat exchanger (3 ), a set of general parallelepipedal-shaped posterior ducts (3M) hollow throughout and arranged vertically, parallel and symmetrically aligned laterally along the back of the heatsink (3K) and inside the anterior chamber (B ) of the heat exchanger (3), and a set of openings (3N) of general circular shapes and arranged vertically, parallel and symmetrically spaced along the entire length of the part. anterior inferior ducts (3L); a set of pairs of openings (30) of general circular shape and arranged vertically and symmetrically spaced and diagonally aligned along the side faces of the heat exchanger (3) in the alignment of the anterior chamber (A) of the heat exchanger (3) ; a set of ducts (3P) of cylindrical general shapes and each symmetrically disposed between a pair of openings (30) and passing through the front chamber (A) of the heat exchanger (3); a gas control valve (3Q) disposed on the outside of the fairing (2) and symmetrically interconnected to the gas burner (3J) through gas ducts and electrical wiring (3R) arranged symmetrically along the full length of the rear chamber ( B) and the heat exchanger base (3), from the control valve (3Q) to the gas burner (3J); and a trapezoidal generally shaped chimney (3S) arranged vertically and symmetrically over the full length of the front opening (3G) and the upper ends of the rear duct assembly (3M) and over the full length of the opening (2J) of the lid ( 21).