RU2338967C2 - Room heater (five versions), room heater jacket and room heater heat exchanger (two versions) - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: room heater includes heat exchanger installed in jacket and fixing supports connected to heat exchanger and jacket. Every support is arranged with at least one part that protrudes above the heat exchanger and interacts with internal surface of jacket. Protruding part of support is installed between internal surface of jacket and heat exchanger and is located along the perimeter of jacket internal surface. Additional air duct may be provided between support and adjacent side wall, which is formed by jacket side wall and extreme parts of top and bottom walls with corresponding air exhaust and intake openings in it. At that in one or two additional air ducts elements might be installed for connection of heat exchanger to heating conduit. At least one air choke may be installed between supports for closure of air exhaust or intake openings. Air filter is fixed to the air choke. Air supercharger is installed in the jacket. Room heater jacket contains casing with bottom, top and side walls. In casing in one of the walls or in all these walls closed apertures are arranged for heating conduits. Every closed aperture is formed by one continuous deepening arranged on internal side of jacket or by several continuous deepenings in jacket wall, which are arranged along aperture perimeter. In idle condition of jacket aperture is fully closed by part of jacket wall limited by perimeter of deepenings, and in working condition aperture is formed by mentioned deepenings along their perimeter. Jacket may be made of transparent material with source of light provided in its cavity. Heat exchanger contains tubular sections connected between each other, every of which includes bottom and top tubular segments connected with vertical tubular segment. Between every pair of adjacent sections in points of their connection to each other, heat exchanging element made of plate is fixed. In heat exchanger ends there are more heat exchanging elements installed that are made of other plates and serve as heat exchanger supports. One end of every additional heat exchanging element has facility for its connection with load bearing element of heated room. The other end of additional heat exchanging element plate is arranged with working surface for its contact with heater jacket. Dimensions of every heat exchanging element installed between heat exchanger sections are less than dimensions of additional heat exchanging element.

EFFECT: reduction of expenses for manufacture and increase of air draught in room heater.

20 cl, 37 dwg

Description

This technical solution relates to facilities for heating rooms and is intended for use in the construction of all types of space heaters.

Convection-type heaters are known, each of which includes a heater or heat exchanger, a box casing in the cavity of which a heater is located, means for connecting the heater to the surface of the heated room [1, 2, 3].

Known space heater, in particular a bimetallic radiator, which is made of interconnected metal tubular sections located in a housing made of aluminum alloy, the housing having a complex structural form, forming a spatial structure with many stiffeners and air channels for the movement of heated air [4] .

The inner case of the radiator is made of steel pipes welded together, forming the lower and upper collectors and vertical channels for moving the coolant along them. The inner case of the radiator is located in the outer case, which is obtained by injection molding by pouring the inner case with aluminum alloy. After the alloy has solidified, both cases of the heat exchanger are removed from the mold, its shell cast from the alloy, which is the second radiator case, is cleaned, processed, ground and painted.

Thus, the well-known bimetallic radiator is made essentially of two cases, the first of which is the inner one, made of interconnected pipes and located in the second outer case, which is obtained by injection molding of an aluminum alloy.

This design of the radiator predetermines a complex technological process using foundry energy-consuming, labor-intensive and environmentally harmful production. Said inner radiator body is made up of a plurality of pipe segments forming interconnected radiator sections, the sections being interconnected by threaded bushings located in the internal holes of the pipe segments forming the upper and lower collectors of the internal radiator body.

The outer casing of a well-known radiator made of alloy has two technical functions, one of which is protective, to protect against burns, and the second function of the outer casing is to generate air flow in a given direction to ensure the movement of heated air from the bottom up during convection. The design of the outer casing of the radiator will also be performed by shaping ergonomic functions.

It should also be noted that the world level of technology includes the use of cast radiators for space heating, the significant disadvantages of which are the production costs for casting and processing radiators, and in the case of convectors with casings, the production costs are associated with the need to use complex construction means for connecting the casing with heat exchanger.

Known space heaters, each of which includes a tubular heat exchanger mounted on the wall of the room, and a casing in which the heat exchanger is located, while the casing is made of a front composite panel and side walls [5, 6, 7].

A significant drawback of these heaters is the complexity of the design of the casing.

Known convector "Isotherm" (four options), characterized by the presence of a casing with a heat package, characterized by a casing in the form of a flat rectangular volume having rounded ribs and vertices, slots in the upper part, and the heat package is an assembly of copper pipes with aluminum fins; The 1st option is characterized by the implementation of the connection unit to the heat package from below, the presence of the control valve of the connection unit, a handwheel (thermostat), air tank, brackets for attaching the convector to the wall, made with the possibility of their movement along the rear wall of the convector; The 2nd option is characterized by the implementation of the connection unit to the heat package from below, the presence of the control valve of the connection unit, a handwheel (thermostat), air reservoir, brackets for attaching the convector to the floor; The 3rd option is characterized by the lateral connection of the heat package to the water heating system and the presence of brackets for attaching the convectors to the wall, made with the possibility of their movement along the rear wall of the convector; The 4th option is characterized by the lateral connection of the heat package to the water heating system and the presence of brackets for attaching the convector to the floor. The disadvantage of this convector is its excessive complexity associated with the need to use means for attaching the heat exchanger to the casing, as well as the need to use a welded casing. Another disadvantage is the relatively large depth of the casing and, as a consequence, the relatively large dimension of the convector in its depth, which leads to the fact that the convector casing protrudes into the space of the room [8].

Known space heater, including a heat exchanger with heat exchange elements fixed to the pipe and a facing panel associated with the heat exchanger [9].

This heater presents a study of the shape of the heater, while there is no constructive connection between the lining and the heat exchanger.

In other technical solutions, the heater heat exchanger is made integral with the facing panel [10, 11, 12].

A heat-generating module mounted against a wall is known, comprising horizontal heat exchange pipes provided with transverse ribs connected to the heating system, the heat exchange pipes being connected to the heating system by means of flexible hoses, the module is additionally equipped with at least two fins with heat insulation on the lower and facing ends of the wall of these ribs and with geometrical dimensions exceeding the geometrical dimensions of the remaining ribs, while the latter are cut in the lower part.

Common features of this technical solution with the room heater presented in this description are signs that the room heater includes a heat exchanger located in the casing and supports connected to the heat exchanger and casing for mounting the heater to the load bearing structure of the heated room [13].

Significant disadvantages of the known heaters are the low degree of their unification, large dimensions in depth (the distance between the wall surface of the heated room and the front surface of the casing), while in the known heaters their depth cannot be reduced for several reasons. The known heater has, in addition, a complex structure and a relatively large complexity of manufacturing.

Achievable and solvable technical task of the present invention is the creation of a unified heater, in which, regardless of the type of heat exchanger used, it is possible to simplify the design and reduce its depth. Another solved and achievable technical task is to simplify the design of the heater, increase the resistance of the casing to bending loads, and also provide the possibility of shallow stamping of the casing by reducing the depth of the casing.

The goals are achieved in that in the space heater, including the heat exchanger located in the casing and the support for connecting the heater to the load-bearing structure of the heated space connected to the heat exchanger and casing, each support is made with at least one part protruding above the heat exchanger interacting with the inner surface of the casing, while the protruding part of the support is located between the inner surface of the casing and the heat exchanger.

The protruding part of each support is located around the entire perimeter of the inner surface of the casing and has an identical shape with the casing in the cross section of the latter.

Each support is made with upper and lower protruding parts interacting with the inner surface of the casing.

Each support is made with upper, lower and middle protruding parts interacting with the inner surface of the casing.

The external dimensions of each support are made larger than the inner contour of the casing in its cross section, while the casing is mounted on the supports with interference.

The shape of the support located in the casing is identical to the shape of the inner contour of the casing, while the casing is connected by means of connection with at least one protruding part of the support.

Each support is made of a plate connected to the heat exchanger with opposite front and rear flanges, the front of which forms at least one protruding part of the support in contact with the casing, and means for connecting the heater to the load-bearing structure of the heated room are made on the rear flange.

The front flange of the plate in contact with the inner surface of the casing is made convex toward the casing, the inner surface of which facing the front flange is made concave with a radius R1 of curvature of the inner surface of the casing, which is less than the radius R of curvature of the front flange in the free position of the casing, while in the casing and holes are made in the front flanging of the plate for connecting the casing with the support.

Each support plate is rigidly connected to the heat exchanger, the front and rear flanges of the plate are connected to the load-bearing structure of the heated room and the casing are detachable, the plate width is greater than the width of the heat exchanger, and gaps are formed between the heat exchanger and the load-bearing structure of the heated room, the heat exchanger and the inner surface of the casing.

The surface of each front flange of the plate is in contact with the inner surface of the casing with at least two of its sections located on opposite sides of the plate.

The front and rear flanges of the plate are directed to one side, and in the front flanging opposite the holes that are made in the rear flanging, recesses are made for the tool.

The front and rear flanges of the plate are directed in opposite directions.

In the room heater, including a heat exchanger located in the casing and supporting the heater to the load-bearing structure of the heated room connected to the heat exchanger and the casing, the casing includes a lower wall with air inlets, an upper wall with air outlets, side walls and a front wall, and casing walls form an air duct, each support is made with a part protruding above the heat exchanger, interacting with the inner surface of the casing, the protruding part o A hole is located between the inner surface of the casing and the heat exchanger, between the support and the adjacent side wall an additional air duct is formed, formed by the side wall of the casing and the extreme parts of the upper and lower walls with the corresponding air outlet and air inlet openings, while elements of the heat exchanger connection are located in the additional air duct with heat conduit.

An additional air intake and air outlet openings are provided in each side wall forming an additional air duct, while air inlet openings are located in the lower part of the side wall, and air outlet openings are located in the upper part of the side wall.

Closed apertures for heat conduits are made in one of the walls or in all of these walls in a room heater casing of a room heater, which contains a casing with lower, upper, and side walls, each closed aperture is formed by one continuous recess or several intermittent recesses in the casing wall located on the inside of the casing located along the perimeter of the opening, while in the idle position of the casing, the opening is closed by a part of the casing wall bounded by the perimeter of the recesses, and in the working position the opening is formed by indented recesses along their perimeter.

In a heater heat exchanger containing interconnected tubular sections, each of which includes lower and upper tubular sections connected by a vertical tubular section, a heat exchanger element made of a plate is fixed between each pair of adjacent sections at the points of their connection, the ends of the heat exchanger are made of other plates additional heat exchange elements, one end of each of which has means for its connection with the load-bearing element of the heated room eniya and the other end of the plate an additional heat exchange element is formed with a working surface for its contact with the casing of the heater, the dimensions of each heat exchange element disposed between the heat exchanger sections is smaller than the dimensions of an additional heat exchange element.

Figure 1 shows the space heater in a spatial image.

Figure 2 - heater, front view (holes shown conditionally).

Figure 3 - the upper part of the casing with air outlets and a shutter.

Figure 4 - heat exchanger heater with two supports, made of separate interconnected tubular sections.

Figure 5 is a fragment of a room heater with a support, the working surface of which is formed by the front flanging of the plate (in longitudinal horizontal section in a top view).

Figure 6 - arrangement of the front deformable flanging plate before and after connecting the casing to the heat exchanger, the first embodiment of the support.

In Fig.7 - support having a working surface formed by the end face of the plate, the second embodiment of the support.

On Fig - support having a working surface formed by a removable elastic compensator before the operation of connecting the casing with the heat exchanger, the third embodiment of the support.

In Fig.9 - a bearing having a working surface formed by a removable elastic compensator after connecting the casing to the heat exchanger, the third embodiment of the support.

Figure 10 - the attachment of the casing to the front flange of the support plate before the operation of fastening the casing in the embodiment of the heater, when R> R1.

Figure 11 - the attachment of the casing to the front flange of the support plate after the operation of fastening the casing in the embodiment of the heater, when R> R1.

In Fig.12 - a heater with a tubular-plate heat exchanger rigidly connected to the support (diagram).

In Fig.13 - a heater with a tubular-plate heat exchanger detachably connected to the support.

On Fig - heater with a tubular heat exchanger made of separate interconnected tubular welded sections and rigidly connected to the support.

On Fig - heater with a tubular-plate heat exchanger connected to the support detachably by means of inclined cutouts in the support plate.

In Fig.16 - a heater with a panel heat exchanger connected to the support detachably by means of vertical cutouts in the plate.

On Fig - arrangement of air dampers on the upper and lower parts of the casing.

On Fig is an embodiment of a room heater with an air blower located in the casing, a filtering air damper located on the lower part of the casing on its outer surface in the outer guides of the casing,

On Fig - layout and execution form of the working surface of the support and the inner surface of the casing in the free position of the latter in the embodiment of the heater, when R <R1.

On Fig - arrangement of connecting elements on the front wall of the casing at R> R1.

On Fig - hole-recess in the front flanging of the plate, forming on the front side of the heater socket under the hole-protrusion of the casing at R1 <R.

On Fig - hole protrusion made in the casing.

On Fig - connection of the casing with the front flanging of the plate at R1 <R.

In Fig.24 - air damper with round holes located in the guides of the lower or upper parts of the casing, view A in Fig.17.

In Fig.25 is a view A in Fig.17, a diagram (a damper is not shown) is a fragment of the casing with air intake holes in it, which are made rectilinear.

In Fig.26 is a view A in Fig.17, a diagram of an air damper with straight holes.

On Fig is a variant of the support with front and rear flanges of the plate, directed in one direction.

In Fig.28 is a variant of the support, which is made of a plate with front and rear flanges directed in opposite directions.

In Fig.29 - section bB in Fig.1, a fragment (the lower air damper on the outer lower part of the casing is open).

On Fig - arrangement of a closed air damper on the outer lower part of the casing in the position when the damper is closed.

On Fig - view And on the lower part of the casing in Fig.17 on the lower arrow (the air damper is removed, the air inlet openings of the casing are round).

On Fig - the second variant of the room heater with a casing, in the side walls of which are made air intake and air outlet openings.

On Fig - section bb In Fig.2.

In Fig.34 is a cross section GG in Fig.33.

On Fig - electrical circuit of the heater.

On Fig - support with an intermittent contact working surface, side view.

On Fig - support with recesses for pipes of the heat exchanger with an intermittent contact working surface, side view.

The room heater includes a casing 1 (Fig. 1) with air outlets 2 in its upper part 3 and air inlets 4 in the lower part 5 of the casing. A feature of the casing 1 is that its upper and lower parts, the right and left side parts are identical in shape and are accordingly interchangeable in the sense that the casing can be turned upside down by mounting it on the wall of the heated room, which corresponds to a rotation the casing around its transverse central soybean 180 ° or rotated 90 ° relative to the mentioned axis. At the same time, since all sides of the casing can be identical in shape, such a casing of the heater becomes as much as possible unified and universal. From the point of view of installation work in construction conditions, this is of significant importance. This advantage also increases the manufacturability of the manufacture of casings.

The casing is made thin-walled and elastic with the smallest possible wall thickness, providing strength and resistance to shock loads from its outer front side. For this, the casing has a hemispherical convex outward shape with a variable hemisphere radius, while in the middle central part of the casing the hemisphere radius is greater than any radius of any portion of the hemisphere that extends from the middle central portion of the casing hemisphere. For casings with S / H / L dimensions equal to 5/50/70 cm, respectively (where S is the depth, H is the height, L is the length of the casing), the central middle hemispherical portion of the casing can be made approximately along the radius R1 (Fig. 10 , 19) in the range of 50–100 cm. Obviously, R1 depends on the elasticity, wall thickness of the casing, and the strength of its material.

The casing may be made of metal with a layer of paint applied to its outer surface, or the casing may be made of colored plastic that does not require coloring, or the casing may be made of transparent plastic with a paint-and-varnish or film coating applied to the inner surface of the transparent casing, the coating can be made in the form of a thin easily removable painted or not painted, with or without an ornament film. If the casing is made translucent, a light source may be located in the casing duct. In this case, the casing acts as a light diffuser.

The design of the heater, in particular its depth S (distance from the trailing edge of the casing or from the wall of the heated room to the inner surface in the center of the casing) and the height H of the casing, are selected from two conditions. The first condition is to ensure a minimum casing depth S and heater power. The second condition is the shape of the casing, which allows it to be produced by the method of shallow stamping with minimal energy consumption instead of existing traditional deep welded casings or instead of casings, which are made of the front panel and connected to it by means of connecting two side walls. It should be noted that welded casings and casings made of side walls and a front panel have a large depth S (due to the high cost of manufacturing deep casings by stamping, traditionally, casings are made either welded or prefabricated from the front panel and the side walls connected to it in a known manner).

Presented in this description of the invention, the casing is made hemispherical, elongated upward and compared to a deep casing, it has a flat shape with a minimum depth, since the casing depth is selected from the condition S = (0.1 ÷ 0.3) N. This ratio makes it possible to stamp the housings by the method of shallow stamping and provides the possibility of increasing the air draft in the housing by increasing the height of the duct and decreasing its passage cross section.

The casing is mounted on the supports 6 (Fig. 4, 5) of the heat exchanger 7. Each support 6 is connected to the casing 1 and the heat exchanger 7 and is made with a working surface 8 in contact with the hemispherical inner surface 9 of the casing 1. Each working surface 8 (Fig. 5) the support 6 is located outside the heat exchanger 7 towards the inner surface 9 of the casing 1 so that between the surfaces 10 of the heat exchange elements 11 of the heat exchanger 7 and the inner surface 9 of the casing 1, an air gap t is formed.

The working surface 8 of each support 6 is made on the front flange 12 of the plate 13 facing the inner surface 9, from which the support 6 is made. Obviously, instead of the plate, another element can be used having means for connecting it to the casing and the wall of the heated room.

Each plate 13 of the support 6 can be rigidly connected to the heat exchanger 7 (figure 4). The plate 13 of the support 6 can also be connected to the heat exchanger 7 detachably (Fig.13, 15, 16).

The plate 13 of the support 6 is made with a rear flange 14 (Fig. 5) located on the opposite side from the front flange 12 and the working surface 8 of the support 6. The working surface 8 of the plate 13 is formed by the front flange 12 of the plate 13 (Figs. 4-6). In one embodiment, the working surface 8 is formed by the end face 15 of the plate 13 (Fig.7) in contact with the inner surface 9 of the casing.

In another embodiment (Figs. 8 and 9), the working surface 8 of the support 6 is formed by a removable elastic compensator 16 located on the end of the plate, which contacts its surface 17 with the inner surface 9 of the casing 1. In the third preferred embodiment, the working surface 8 of the support 6 is formed by the front flange 12 of the plate 13 (Fig.4-6) in contact with the inner surface 9 of the casing 1.

In one embodiment of the heater, the shape of the working surface 8 of each support 6 is solid (the left part in FIG. 4) and repeats the shape of the inner surface 9 of the casing. In another embodiment of the heater (FIGS. 13 and 15), the shape of the working surface 8 of the support 6 is made along the contour of the inner hemispherical surface 9 of the casing 1, however this working surface 8 is not made continuous, since there are cutouts or recesses 18 in the plate 13.

On the inner surface 9 of the casing 1 (Fig.17) along its length between the working surfaces 8 of the two supports 6, which are shown in Fig.4, in the lower part 5 of the casing or in the upper part 3 of the casing or simultaneously in the lower and upper parts of the casing movably along one or two air dampers 19 are installed in it. Each damper 19 has a plurality of circular holes 20 (Fig. 24) with a diameter D. These openings are identical in shape to the air inlets 4 or the air outlets 2 of the casing. Between the openings 20 of the shutter 19, jumpers 21 are made, the width W of each of which is selected from the condition W≥D. If in the casing 1, the holes 2 or 4 (Fig. 25) are made in the form of transverse slots, then the width W of each jumper 21 between the holes 2 or 4 is selected from the condition of overlapping by the jumper 21 of the shutter 19 (Fig. 26) the width D of the hole 20 of the casing 1 (Fig.25) when moving the flap along the casing by a step equal to the width W of the jumper 21 of the flap 19 (Fig.26). With any form of holes (in the form of slots or in the form of round holes), the width of each jumper 21 of the shutter 19 is selected so that it can overlap both partially and completely adjacent to it the air intake hole 2 or the air outlet 4 of the casing when moving the flap 19 along the casing in both directions. Approximately the movement step of the shutter is in the range from 2 to 5 mm. Each, upper or lower, shutter 19 is made of thin, light and elastic, with a high degree of sliding material. Each damper is installed in the guides 22 of the casing (Fig. 18) with the possibility of its easy sliding in them and has a manual or electromagnetic drive, described below.

In one preferred embodiment of the heater (FIGS. 4, 5, 12), the casing 1 can be fitted with its inner surface 9 onto the working surfaces 8 of the supports 6 with an interference fit, while the casing 1 is connected to the working surfaces 8 of the supports 6 by frictional forces between the inner surface 9 the casing and the working surfaces of the 8 supports 6 due to the elasticity of the casing and tightened its upper and lower parts to the supports 6.

Each working surface 8 of the support 6 in a preferred embodiment of the heater is made curved convex towards the casing 1 in the transverse plane along the radius R. The inner surface 9 of the casing is made curved concave in the transverse plane along the radius R1. Moreover, the heater (Fig. 19) provides an option for R1> R in the position of the casing, when it is not connected to the supports 6 and is in a position free from the supports. The difference in the radii of curvature of the support 6 and the casing 1 is provided for the design of the heater, in which the casing 1 is attached to the support 6 by fasteners 23 (Figs. 10, 11) with different radii R1 and R. A variant of such a connection of the casing with the heat exchanger is described below. It should be noted that in the first embodiment of fastening or fixing the casing on the supports 6 due to the friction forces and the elasticity of the casing R1 = R.

The inner surface 9 of the casing can be made concave in two horizontal and vertical planes (FIG. 1) or in one horizontal longitudinal plane in order to provide rigidity and stability of the front front wall of the casing to the action of bending forces. Since the front face of the casing 1 is the most vulnerable to impacts during the production of the casing, its transportation and operation, the internal concavity of the casing in one transverse plane or in two planes (transverse and longitudinal) characterizes the heater as a convex heater. A casing made by stamping with a minimum depth S (Fig. 1) between the rear edge of the casing and the farthest point Q, located on the inner surface of the casing, is a slightly convex outward design that provides (with constant heater power) the possibility of increasing the height H the casing and the height of the duct, reducing the bore of the duct and, as a consequence, increasing the air draft in the duct of the casing formed by the wall of the heated room and internal 9 NOSTA casing.

During the assembly of the heater at the construction site, when the inner surface 9 of the casing is pressed against the working surface 8 of each support 6, the aforementioned small difference in the radii R1 and R (Fig. 10) of the curvature of the casing 1 and support 6 is compensated by the elasticity of the casing and these radii become equal ( 11). For reliability of fastening the casing to the supports, the casing 1 can be pressed (Fig. 10, 11) to the supports 6 in one of the heater designs with fasteners 23 located in the holes 24 of the casing 1 and the holes 25 of the support 6. In this case, the fasteners 23 can be located closer to the upper and lower parts of the casing according to the scheme shown in figure 2. The fasteners 23 can be located closer to the middle part of the casing, as shown in Fig.20. The location of the fasteners 23 depends on the curvature R1 and R and the elasticity of the casing 1. If R1> R, then the fasteners are located in the middle part of the casing, as shown in Fig.20. When performing the heater, when R1 <R, fasteners 23 are located in the upper and lower parts of the casing (figure 2). Fasteners 23 are self-tapping screws for connecting thin-walled structural elements. However, as fasteners connecting the casing 1 with the supports 6, other elements described below can be used, for example, recesses or protrusions made on the working surface 8 of the support 6, and mating protrusions or recesses made on the inner surface 9 of the casing.

For fastening the heater to the wall of the heated room (Fig. 4, 5), holes 26 or grooves 27 (Fig. 27) are made in the rear flange 14 of each support 6 for mounting means 28 (Fig. 4) of the support 6 to the wall 29 (Fig. 5 ) a heated room. On Fig grooves 27 are made oblique, however, they can be made straight, located at right angles to the rear flange 14.

In the design of the space heater, a tubular-plate heat exchanger 30 (Fig. 12, 13 and 15, 18), a tubular heat exchanger 7 (Fig. 14) made of sections 31 with plates between the sections (Fig. 4), a panel heat exchanger 32 can be used (Fig.16), as well as other types of heat exchangers. In any of these uses of said heat exchangers, uniform supports 6 are used which are rigidly or releasably connected with said heat exchangers and with a load-bearing part of the building.

On Fig in one of the embodiments of the connection of the casing with the support 6 shows the recess 33 in the front flange 12 of the plate 13 of the support 6. In Fig.22 shows the protrusion 34 made in the casing 1. In the operating position of the heater, the protrusion 34 is located in the recess 33 ( Fig.23). Other options for connecting the casing 1 with the supports 6 are possible.

The design of the space heater presented in this description of the invention provides for the possibility of using the heater as a stationary vacuum cleaner to clean the dust of the room air that circulates in the heated room passing through the room heater. For this, an easily removable and replaceable air filter 35 (Fig. 18) is mounted on the lower flap 19 (Fig. 18), while the flap is placed on the outer surface of the casing in the guides 22, which are also located on the outside of the casing.

If the casing is made of transparent plastic that transmits light, the room heater can be used as a lamp. To this end, a light source 36 is placed in the heater’s duct, inside the casing (Figs. 18, 35), in particular one or two small-capacity electric lamps electrically connected to a power source, in particular, a mini-battery recharged if necessary.

If the plates 13 of the supports 6 (Fig. 4) are respectively made with the front and rear flanges 12 and 14 directed to one side, then the front flanges 12 make recesses 37 for the mounting tool (not shown), by which the fastening means 28 are screwed the wall. The recesses 37 are located on a straight line support perpendicular to the rear flange opposite the holes 26 that are made in the rear flange 14, or opposite the oblique grooves 27 (Fig. 27). If the flanges are directed in opposite directions (Fig. 28), then said recesses in the front flanges 12 are not performed.

Since the heater casing 1 has the smallest possible depth S, the pipe 38 (FIG. 5) and pipe 39 (FIG. 4) located therein are connected to flexible supply and exhaust heat pipes 40 and 41, respectively, from the layout requirements of the described compact heater ( 5) fittings 42, the diameter of each tube of the heat conduit 40 or 41 is less than the diameter of the pipe 38 or 39. The heat conduits 40 and 41 enter and exit the duct duct 1 through the lower opening 43, which is made as in the lower wall. The openings 43 can be made in any other wall (in two side and upper walls) - depending on the layout of the heater, its left, right, upper or lower connections to heat pipes 40 and 41, and also depending on whether the heater is a walk-through heater (with two openings 43 for heat conduits) or impassable (with one opening 43 for heat conduits). Figure 2 shows the dotted line of the possible location of the heat pipes 40 and 41 in a heated room.

According to the options for the location of the heat conductors in the walls of the casing by the method of plastic deformation of its walls, special recesses 44 (Fig. 34) are made, forming a dashed contour 45 (Fig. 33), along which a part of the casing wall corresponding to the location of the heat conductors is extruded during installation of the heater, and thus , an opening 43 is formed (Fig. 5) for heat conduits. The optimal solution to the task of creating a universal casing is to make the recesses 44 and the formation on the walls of the casing (including the upper wall) of several circuits 45 for various possible location of the heat pipes 40 and 41 in the upper, side and lower walls of the casing. Recesses 44 in the upper wall of the casing are provided in the case when the casing is made with identical upper and lower parts 3 and 5 (Fig. 2) and the heat pipes are connected to the heater from above.

A second embodiment of a room heater is provided (Fig. 32). This heater also includes a heat exchanger located in the casing and supports for mounting the heater to the load-bearing structure of the heated room, in particular to the wall 29 of the room, connected with the heat exchanger and the casing (Fig. 5). In this embodiment, the casing includes identical lower and upper walls 46 (Fig. 32) with air outlet and air inlets 2 and 4, side walls 47 and 48 and the front wall 49. The room wall 29 (Fig. 5) and said casing walls form an air duct 50. Each support 6 of this embodiment of the heater is also (as in the first embodiment) made with a part protruding above the heat exchanger, forming a contact working surface 8 (figure 4), interacting with the inner surface 9 of the casing (figure 5). The protruding part with the working surface 8 of the support 6 is also located between the inner surface 9 of the casing and the heat exchanger 7. In contrast to the first variant, additional air ducts 51 are formed between each support 6 and the adjacent side wall 47 or 48 (FIG. 5), in which heat exchanger elements are located, for example, means for connecting the heat exchanger to the heat pipes, in particular fittings 42. Each additional duct 51 is formed by a side wall 47 or 48 of the casing and the extreme parts of the upper and lower walls 46 of the casing (Fig. 32), respectively air outlet and air intake openings in them.

In the additional air ducts 51 forming the side walls 47 and 48, additional air inlets 52 (FIG. 32) and air outlets 53 are provided. Air inlets 52 are located in the lower part of each side wall 47 and 48, and air outlets 53 are located in the upper part of each side wall casing 1.

To move the shutter 19, a device is provided (Fig. 35) comprising a temperature sensor 54 connected to a power supply circuit 55, which is connected, for example, to a mini-battery. The sensor 54 is also connected to the electromagnetic mini-drive 56 for moving the air damper 19 and the mini-drive 57 for rotating the supercharger 58 of the air into the heater duct. The supercharger 58 of the air is made in the form of a screw from an ultralight material, for example, from tissue paper reinforced on aileron glued. An electric lamp 36 or two low-power electric lamps are included in the power supply circuit 55. Position 59 in Fig.16 shows the groove in the support 6, in which the panel heat exchanger 32 is freely located.

An embodiment of an independent technical solution, in particular, a heat exchanger 7 of a heater (FIG. 4), comprises tubular sections 31 interconnected, each of which includes lower and upper horizontal tubular sections 60, interconnected by a vertical tubular section 61. Between each pair of adjacent sections 31, at the points of their connection with each other, a heat-exchange element 62 made of a plate is fixed (not all heat-exchange elements 62 are conventionally shown in FIG. 4). At the ends of such a heat exchanger 7, as mentioned above in the heater description, additional heat exchange elements made of other plates 13 are installed, which at the same time serve as supports 6. One end of each additional heat exchange element has a means or flange 14 for connecting it to the load-bearing element of the heated room , in particular with the wall 29 of the room, and the other end of the plate of the additional heat exchange element is made with a working surface 8 for its contact with the casing 1 of the heater . The overall dimensions of each heat exchanger element 62 located between the sections 31 of the heat exchanger 7 are smaller than the overall dimensions of the plates 13 of the additional heat exchange element.

The space heater works as follows. In the case of performing a universal casing (with several circuits 45 mentioned in it (Fig. 33), formed by recesses 44 (Fig. 34)) to form openings 43 (Fig. 5) for heat pipes 40 and 41, depending on the location of the heat pipes (Fig. .2), a part of the casing wall is extruded along the corresponding contour 45 (Fig. 33), forming an opening 43 (in Figs. 32 and 33, the opening 43 is shaded). Next, the heat exchanger 7 (Fig. 4) is fixed on the wall 29 of the heated room by means of fastening 28, the pipes 38 and 39 of the heat exchanger are connected to the heat pipes 40 and 41 by fittings 42 as shown in Fig. 5, and then the casing 1 is put on the supports 6, while having the heat conduits 40 and 41 in the opening 43. In a similar manner, a heater is assembled having heat exchangers of other types that are rigidly connected to the supports 6.

If the heat exchanger 7 is connected to the supports 6 detachably (Fig. 13, 15), then the supports 6 are mounted on the wall 29, and then on these supports, in their recesses 18, the elements of the heat exchanger are fixed, for example, the heat exchanger pipes, as shown in 13 and 15. After that, the heat exchanger 7 is connected to the heat pipes 40 and 41, and then on the supports 6 put on the casing 1 of the heater. When installing the casing on the supports 6, the opening 43 (Fig. 5) covers the heat conductors 40 and 41 from any of the sides of the heat conductors indicated in Fig. 2.

Heating the room is as follows. Through the air inlet openings 4 (FIG. 1), cold air enters the casing 1, is heated in it by the heat exchanger 7, rises due to the air draft in the casing duct, and exits through the casing air outlets 2 into the heated room.

Since the shutter 19 or two such shutters (Fig. 17) are always closed in a cold room, then at a certain temperature of the heat exchanger 7, the sensor 54 is activated (Fig. 35) and turns on the electromagnetic drive 56 for moving the shutter 19, which moves in the guides of the casing. When moving the damper partially open or completely open holes 2 and 4 or only one hole 2 or only one hole 4. In this case, air draft forms in the duct 50 of the casing (Fig. 5) and convective more intense heat exchange occurs between the heat exchanger 7 and the air column in duct casing. In this case, the consistency of the two casing shutters depends on the temperature of the heat exchanger and the air of the heated room. The movement of the shutter (in the range from 3 to 5 mm) is performed by a step W (Fig. 24) equal to D, where D is the diameter of the round opening of the casing or the width of the slit of the casing.

If it is necessary to increase the heat in the heated room, the mini-drive 57 of the air blower 58 is switched on from the temperature sensor 54 (Fig. 18, 35). The latter draws air into the casing through the intake holes 4, pumps it into the casing duct 50 and provides an even more intense heat exchange between the heat exchanger 7 and the air flowing around it. The heated air by the blower 58 is pushed out of the casing 1 through the air outlets 2 of the casing.

When the heater operates both with and without air blower 58, the heater simultaneously functions as a vacuum cleaner. At the same time, air passing through the air intake holes 4 (Fig. 18), through the pores of the air filter 35 and the holes of the lower damper 19 is filtered by the filter 35 and is cleaned of dust, which is trapped in the pores of the filter. Dust from the filter is periodically removed during vacuuming or the filter clogged with dust is replaced with a new filter.

In the case of using a casing made of transparent or translucent plastic, the heater can be used as a lamp. To do this, include located in the casing of the lamp 36, and the casing in this case acts as a light diffuser.

Features are provided for attaching the casing 1 to the supports 6. In the event that in the cross section of the casing 1 its inner surface 9 is identical in shape to the surface of each support 6 (Fig. 12), then the casing is put on the supports with interference and is fixed on the supports 6 due to elasticity the casing and the adhesion between the inner surface of the casing and the inner surfaces of the lower and upper walls of the casing. The casing may be in another design is fixed to the supports with screws 23 (Fig.11). If in the cross section of the casing 1 (Fig. 19), its inner surface 9 differs from the outer working surface 8 of the protruding part of the support 6, for example, provided that R1 is greater than R, then in this case, with an interference fit, the casing is brought into the upper and in the lower recess 33 (Fig.21) of the support 6, the protrusions 34 (Fig.22) as shown in Fig.23 and, thus, fix the casing 1 on the supports 6. In this case, the difference between R1 and R makes it possible to tighten the casing on the supports 6 and tight contact of the inner surface 9 of the casing with the working surfaces 8 of the supports. The density of the contact of the surface of the casing with the working surfaces of the supports increases the resistance to bending of the casing from the outside by damping the external loads on the casing of the supports 6. From the point of view of maximum resistance of the casing, it is desirable that the casing is in contact with the support along its entire perimeter in the contact zone. With the available margin of resistance to bending of the casing, each support 6 may have a wave-like shape (Fig. 36) with an intermittent contact working surface 8 or another shape (Fig. 37) with an intermittent contact surface 8, interacting with the inner surface 9 of the casing. In this case, the connection of the casing with the supports is carried out in a manner known or described above.

When R1 is greater than R (Fig. 19), the contact density of the inner surface 9 of the casing with the working surface 8 of each support 6 is compensated by the difference of the mentioned radii, while this difference provides for errors in the manufacture of the casing and supports and this difference is practically negligible.

The contact density of the casing with the supports can also be achieved due to the elasticity of the flanges 17 (Fig.6), which, when in contact with the inner surface 9 of the casing, are bent toward the wall 29 of the room by δ and in the bent state they occupy the working position shown in Fig.5. With the exact manufacture of the casing and the heat exchanger, the contact of the inner surface 9 of the casing with the support 6 is possible through the end face 15 of the support (Fig.7). In another embodiment, the end face of the support 6 can contact the inner surface 9 of the casing through an elastic elastic compensator 16 worn on the end of the support 6. In this case, the contact of the support 6, in particular the plate 13 of the support 6, is carried out with the casing through the contact surface 17 of the compensator forming the contact the working surface in contact with the inner surface 9 of the casing. It should be noted that the tight contact of the casing with the supports through an elastic compensator ensures the heater is resistant to shock loads from the outside of the casing, and such shocks during the long-term operation of the heater are inevitable. In the case of the use of elastic compensators 16, a soft elastic fit of the casing on the supports is achieved, due to which the shock loads on the casing are absorbed.

When using panel heat exchangers 32 (Fig. 16), first, in the vertical grooves 59 made in the supports 6, the heat exchanger 32 is inserted by moving it in the horizontal direction, then the supports 6 are attached together with the heat exchanger to the room wall, and then the casing 1 is put on the supports 6 as described above.

The use of this technical solution, including a casing, supports and any heat exchanger, shown in Fig.12-16, provides significant advantages with respect to the versatility of the casing and the widespread unification of heater components that can be used in all types of heaters. It creates the possibility of manufacturing simple in design flat heaters with minimum dimensions in depth, with increased air draft. This creates the possibility of manufacturing a heater casing by its shallow stamping. The shallow casings, uniform in size, do not significantly affect the interior of the heated room, since they protrude minimally from the wall of the room into its space.

An embodiment of an independent technical solution, in particular the heat exchanger 7 shown in Fig. 4, provides the possibility of increasing heat transfer, creating a powerful (flat) heat exchanger at the minimum cost for its manufacture, because in comparison with similar sectional so-called bimetallic heat exchangers requiring casting and significant surface treatment, the heat exchanger described in this invention does not require any treatment, since all In the working position, the enclosures are closed by a casing as described above.

Information sources

1. RU 16306 S, F24H 3/06.

2. RU 2145691 C1, F24H 3/06.

3. Convector novelty, Santekhprom Avenue, M., 2003, p.2.

4. Recommendations on the use of bimetallic sectional heating radiators "Santechprom BM" manufactured by OAO "Santechprom". Scientific-production company LLC Vitaterm, M., 2001, p.5.

5. JP 890586, 23-03.

6. JP 900978, 23-03.

7. JP 900977, 23-03.

8. RU 43070S, 23-03.

9. CZ 2098990 S, 23-03.

10. AT 25419 S, 23-03.

11. AT 25426 S, 23-03.

12. AT 25430 S, 23-03.

13. RU 2001359 C1, F24H 3/06 (prototype).

Claims (20)

1. A room heater, including a heat exchanger located in the casing and supporting supports of the heater to the load-bearing structure of the heated room associated with the heat exchanger and the casing, characterized in that each support is made with at least one part protruding above the heat exchanger interacting with the inner surface of the casing while the protruding part of the support is located between the inner surface of the casing and the heat exchanger, and the protruding part of each support is located around the perimeter of the inner surface casing 2. The heater according to claim 1, characterized in that the protruding part of each support has an identical shape with the casing in the cross section of the latter. 3. The heater according to claim 1, characterized in that each support is made with upper and lower protruding parts interacting with the inner surface of the casing. 4. The heater according to claim 1, characterized in that each support is made with upper, lower and middle protruding parts interacting with the inner surface of the casing. 5. The heater according to claim 1, characterized in that the external dimensions of each support are made larger than the inner contour of the casing in its cross section, while the casing is mounted on supports with an interference fit. 6. The heater according to claim 1, characterized in that the shape of the support located in the casing is identical to the shape of the inner contour of the casing, while the casing is connected by means of connection with at least one protruding part of the support. 7. The heater according to claim 1, characterized in that each support is made of a plate connected to the heat exchanger with opposite front and rear flanges, the front of which forms at least one protruding part of the support in contact with the casing, and are made on the rear flange means for connecting the heater to the load-bearing structure of the heated room. 8. The heater according to claim 7, characterized in that the front flange of the plate in contact with the inner surface of the casing is convex toward the casing, the inner surface of which is facing the front flange, made concave with a radius R1 of curvature of the inner surface of the casing, which is smaller than the radius R of curvature front flanging in the free position of the casing, while in the casing and in the front flanging of the plate, holes are made for connecting the casing with the support. 9. The heater according to claim 7, characterized in that each support plate is rigidly connected to the heat exchanger, the front and rear flanges of the plate are connected to the load bearing structure of the heated room and the casing is detachable, the plate width is greater than the width of the heat exchanger, and between the heat exchanger and the load bearing structure is heated the room, the heat exchanger and the inner surface of the casing formed gaps. 10. The heater according to claim 7, characterized in that the surface of each front flanging of the plate is in contact with the inner surface of the casing with at least two of its sections located on opposite sides of the plate. 11. The room heater according to claim 7, characterized in that the front and rear flanges of the plate are directed to one side, and in the front flanging opposite the holes that are made in the rear flanging, recesses are made for the tool. 12. The space heater according to claim 7, characterized in that the front and rear flanges of the plate are directed in opposite directions. 13. A room heater, including a heat exchanger located in the casing and connected to the heat exchanger and the casing, supports mounting the heater to the load-bearing structure of the heated room, the casing comprising a duct forming a lower wall with air inlets, an upper wall with air outlets, side walls and a front wall, characterized in that each support is made with a protruding part above the heat exchanger interacting with the inner surface of the casing, the protruding part of the supports is located between the inner surface of the casing and the heat exchanger, between the support and the adjacent side wall an additional air duct is formed, formed by the side wall of the casing and the extreme parts of the upper and lower walls with the corresponding air outlet and air inlet openings, there are elements for connecting the heat exchanger to the heat conduit in the additional air duct, between the supports movably along the casing, at least one air damper is installed. 14. The space heater according to claim 13, characterized in that additional air inlet and air outlet openings are made in each side wall forming an additional air duct, while air inlet openings are located in the lower part of the side wall and the air outlet openings are located in the upper part of the side wall. 15. The casing of the space heater, comprising a casing with lower, upper and side walls, characterized in that closed openings for heat conduits are made in one of the walls or in all of these walls, each closed opening is formed by one continuous recess located on the inside of the casing or several intermittent recesses in the wall of the casing located along the perimeter of the opening, while in the idle position of the casing, the opening is closed by a part of the wall of the casing limited by the perimeter of the recesses, and in the working polo The opening is formed by the said recesses along their perimeter. 16. The heat exchanger of the heater, containing interconnected tubular sections, each of which includes lower and upper tubular sections connected by a vertical tubular section, characterized in that between each pair of adjacent sections at the points of their connection to each other, a heat exchanger element made of a plate is fixed to the ends of the heat exchanger are installed made of other plates additional heat transfer elements that perform the functions of the supports of the heat exchanger, one end of each additional heat exchange the element has means for its connection with the load-bearing element of the heated room, and the other end of the plate of the additional heat exchange element is made with a working surface for its contact with the heater casing, and the overall dimensions of each heat exchange element located between the heat exchanger sections are smaller than the overall dimensions of the additional heat exchange element . 17. A heat exchanger of a heater comprising interconnected heat exchange elements, characterized in that at the ends of the heat exchanger along its length there are additional heat exchanger elements arranged in such a way that one end of each additional heat exchanger element has means for connecting it to a load-bearing element of the heated room, and the other end of the additional heat-exchange element is made with a working surface for its contact with the casing of the heater, and the overall dimensions of each The main heat exchanger element of the heat exchanger is smaller than the overall dimensions of the additional heat exchanger element. 18. A room heater, including a heat exchanger located in the casing and associated with the heat exchanger and the casing, supports for mounting the heater to the load-bearing structure of the heated room, the casing including a lower wall with air inlets, an upper wall with air outlets, side walls and a front wall, casing walls form an air duct, characterized in that each support is made with a part protruding above the heat exchanger, interacting with the inner surface of the casing, the falling part of the support is located between the inner surface of the casing and the heat exchanger, between the support and the adjacent side wall an additional air duct is formed, formed by the side wall of the casing and the extreme parts of the upper and lower walls with the corresponding air outlet and air inlet openings, while in one or two additional ducts are the elements of the connection of the heat exchanger with the heat conductor, between the supports movably installed along the casing at least one air damper, covering the air exhaust or intake openings of the upper or lower walls, an air filter is attached to the damper, and an air blower is installed in the casing. 19. A room heater, including a heat exchanger located in the casing and supporting supports of the heater to the load-bearing structure of the heated room associated with the heat exchanger and the casing, the casing includes a lower wall with air inlets, an upper wall with air outlets, side walls and a front wall, the walls of the casing form an air duct, characterized in that each support is made with a part protruding above the heat exchanger, interacting with the inner surface of the skin ha, the protruding part of the support is located between the inner surface of the casing and the heat exchanger, between the support and the adjacent side wall an additional air duct is formed, formed by the side wall of the casing and the extreme parts of the upper and lower walls with the corresponding air outlet and air inlets in one or two additional ducts are the elements of the connection of the heat exchanger with the heat conductor, between the supports movably installed along the casing at least one air damper, covering the air exhaust or intake openings of the upper or lower walls, at least one air filter is installed on the air damper of the casing, an air blower is installed in the casing. 20. The space heater, including the heat exchanger located in the casing and the supports attached to the heater to attach it to the load-bearing structure of the heated room, characterized in that the casing is made of transparent material and a light source is installed in its cavity.

Images