HU220805B1 - Heating apparatus producing radiant and convective heat - Google Patents

Abstract

A heating apparatus comprising a heating pipe element (1) emitting radiant heat, a reflector (2) arranged along at least one part of the length of the heating pipe element (1) and having a longitudinal edge part (7) on each side of the heating pipe element (1), a hood (4) arranged above at least one part of the reflector (2), and a fan (5) associated with a space between the hood (4) and the reflector (2) in order to forward heated air (3) to a required place. At least on one side of the heating pipe element (1) the hood (4) has a longitudinal edge part (8) projecting laterally and downwards over the longitudinal edge part (7) of the reflector (2) on the same side, thereby determining at least one longitudinal intake opening (10) for the heated air (3) flowing upwards into the space between the hood (4) and the reflector (2).

Description

BACKGROUND OF THE INVENTION The present invention relates to radiant heat and convection heat generating apparatus for heating large enclosed or partially open interiors and exteriors of large buildings and ceilings.

Current heating practices include, but are not limited to, gas-fired radiant heaters, but also, for example, hot water, steam or electric radiant heaters. Heating with tubular heaters is generally more economical than other conventional heaters such as hot-air or radiators because the same sensory temperature can be provided at lower air temperatures due to the heat sensing effect of the radiant heat.

Radiant tube heaters are usually located in the upper part of the spaces to be heated, and reflectors arranged above the radiant tubes are widely used to reflect the heat emitted by the radiant tubes upwards. However, the jet heated by the flue gas, medium or electric current flowing in the jet stream not only emits radiant heat but also so-called convection heat by direct heating of the air. The problem is that due to the specific gravity of the heated air carrying the convection heat emitted by the radiator tube and the reflector, it flows upwards and does not heat the lower part of the space to be heated. Convection heat ratios are significant, with conventional tubular heaters the convective heat output of the reflector is about 5-8% of the heat input, and the convection heat released by the tube is about 30-40% of the heat supplied.

A solution to reduce the convection heat emitted by the reflector is known to be provided with an insulating material on its upper surface. However, this can only slightly reduce the amount of convection snow released. Another solution for utilizing convection heat is that hot air collected and mixed in the upper airspace of the space to be heated is introduced into the work space in the lower space of the space by large ceiling fans. However, this solution requires disadvantageously high performance and noisy fans in order to provide a sufficient amount of warm air to the work area. In addition, the convection heat generated by the ceiling fans cannot be utilized directly.

Combined convection / radiant heaters are described, for example, in WO 98/46946. This known heater comprises a radiant heat-emitting gas heater tube located at the top of the space to be heated, a "heat exchanger plate" arranged above the heater tube, the reflector itself, and a lower open hood over the reflector from above and from the side. . The blower fan blows air from the upper space between the canopy and the reflector, which is heated by the reflector and canopy and flows down through the gaps between the longitudinal edges of the canopy and the reflector.

The problem with this known solution is that when the gaps are narrow, the air jet melts into the air space relatively shortly without entering the work space. If the gaps are wide, relatively large volumes of air will require high-power and heavy-duty fans, and the exhaust air may not be hot enough and may exert a cooling effect on human skin at certain air velocities. If, on the other hand, the jet of air is used to create a warm feeling, it will produce it in the part of the work area where the heat of heat is anyway the highest.

It is also a problem that downward, relatively high velocity air jets have a significant injection effect, which accelerates the flow conditions at the radiator tubes. The turbulence effect of accelerated flows, due to the increase in heat transfer coefficient, cools the radiator tubes better, i.e. the heating tubes become colder. A slight cooling of the radiator tubes causes a significant reduction in radiant heat since the radiant heat released to the environment is proportional to the difference between the fourth power of the absolute temperature of the radiator and the fourth power of the absolute temperature of the environment. And with radiant tube heating, the goal is usually to get as much radiant heat into the work area as possible. Therefore, cooling the pipe reduces the efficiency of the heating.

Radiant tube heating apparatus is further described in DE 32 17 948 A1. In this known heater, the heat emitted by the riser is discharged upwardly by a flow of air in a duct above the heater. The air thus heated is circulated to the lower part of the space to be heated or to any other desired location. The air flowing in a duct consisting of a reflector-shaped lower profile and a top-side mating-like profile connected thereto seeks to capture both radiant heat and convection heat, which are discharged laterally or upwards. Also described herein is the possibility of providing openings in the lower profile of the channel for direct collection of convection heat.

The disadvantage of this known solution is that it cannot collect all the convection heat without openings in the lower profile of the channel, but utilizes almost exclusively the radiated heat released upwards. This means that the air heated by the heating pipe flows upwardly from the lower profile of the duct downwards. On the other hand, the air circulated in the duct cools the duct, which indirectly exerts a cooling effect on the running pipe, which reduces the efficiency of radiant heating. The openings in the lower profile of the duct can now collect all the convection heat with the duct, but these openings greatly accelerate the flow of air around the trunnion, leading to even greater cooling of the boiler. Thus, the solution cannot utilize convection heat so that the maximum amount of radiant heat remains. A further disadvantage is that minor interferences with the operation of the heater, such as draft draft, changes in operating temperature due to changes in the calorific value of the heating gas, etc. it significantly modifies the convection / radiant heating ratio set.

HU 220 805 Bl

In the context of the present invention, it is an object of the present invention to provide a tubular heater capable of utilizing all of the convection heat generated while maintaining the maximum radiant heat output. The use of convection heat means that the heated air produced by convection is directed in a controlled manner to the work area or other desired location. It was also our aim to develop a radiant tube heater that is less susceptible to interference in the use of convection heat.

In order to achieve the object of the present invention, it is essential to study the flow patterns of the tubes. Underneath the reflector above the radiator tubes, for example, a substantially horizontal boundary layer is formed between the hot air exiting the reflector and the lower temperature air below the reflector, which can be detected by a smoke test. Significant horizontal velocities occur in the air cushion above the boundary layer, which have, on the one hand, a tubular component (to compensate for longitudinal temperature differences) and, on the other, a component perpendicular to the tube, which is actually proportional to convection heat exiting the reflector. The flow of air with a velocity component perpendicular to the tube bends upward from below the reflector. Of course, there is intense upward flow underneath the radiator tube to replace the upwardly inflated air. To remove all convection heat generated, the longitudinal change in convection, the internal equilibrium caused by the change, and the magnitude of the heat generated alone must be considered. Flow conditions are also affected by the non-horizontal placement of the tube. Determining the amount of convection heat to be discharged, and thus the technical design of the drainage, is only possible by approximation, since the flow conditions are influenced by the operating conditions, temperatures and draft conditions in the space to be run.

It is a further object of the present invention to provide a design that allows significant tolerances in sizing without the cooling of the radiator tubes due to excessive air flow. This ensures that the full convection heat can be properly utilized while maintaining the maximum radiation effect.

As stated above, the apertures in the reflector reduce the radiation efficiency. The suction flow lines formed around such openings practically do not favor any suction direction, but also exhibit a near-symmetrical flow pattern, taking into account interfering factors. Therefore, such openings must be dimensioned with great precision and theoretically unchanged operating conditions in order to dissipate the resulting convection heat. The apertures, as they enter the flow zones naturally formed in the tubes, cause turbulence and excess airflows that have a cooling effect on the tube. The horizontal inlet on the reflector rim is not the most appropriate design as its flow conditions are also symmetrical. This means that if the amount of exhaust air is small, some of the convection heat will escape, and if high, it will speed up the flow conditions under the reflector.

In order to overcome all these problems and to achieve the above objectives, the present invention provides a radiant heat and convection heat generator comprising a radiant heat transfer truss member at least a portion of the length of the truss member having a radially extending peripheral portion on its two sides. a reflector arranged over at least a portion of the reflector, and a fan connected to the space between the reflector and the reflector to transfer the heated air therein to a desired location. According to the present invention, the umbrella has at least one side of the running member that defines at least one longitudinal suction opening for laterally and downwardly extending the heated air entering the space between the umbrella and the reflector, extending laterally and downwardly from the longitudinal edge portion of the reflector. and the heated air entering the space between the reflector is conveyed to the desired location by suction from the space by the fan.

The design of the present invention allows the total convection heat generated to be removed and applied to the desired location. By providing a convection heat suction inlet according to the invention, a convection heat recovery solution of a self-regulating type is obtained over a relatively wide interval, in which the position of the boundary layer changes extremely little. In this way, the total amount of convection heat is eliminated without having to reckon with any cooling of the tread element. The self-regulating design is relatively large, allowing for a flow rate change of ± 50% relative to the mean value, or a change in intake opening width.

In a preferred embodiment of the invention, the reflector is arranged at a height substantially equal to the longitudinal flange portion of the reflector and has a longitudinal flange defining a longitudinal suction opening on each side of the flare member. This design is advantageous for ceiling mounted heaters. It is advantageous for deflecting the convection air flow if the longitudinal flange portions of the reflector are formed outwardly and upwardly from the trunnion element and the longitudinal portions of the screen are inclined towards the trunnion element.

In another preferred embodiment, one of the longitudinal edge flange portions of the reflector is located at a higher height relative to the heater tube member, wherein the at least one longitudinal suction opening is formed at a higher longitudinal edge flange portion of the reflector. This design is advantageous for wall-mounted heaters. In this case, the longitudinal edge portion of the reflector, preferably arranged at a higher height, is formed outwardly and upwardly from the running pipe element, the screen being laterally and downwardly extending.

The longitudinal edge portion of the HU 220 805 Β1 horse is bent downwards.

It is particularly advantageous to have a longitudinal slot smaller than its width in the direction of the flow of heated air in the space between the screen and the reflector, upstream of the at least one longitudinal inlet. With this slit, the amount of exhaust air can be properly regulated, while the width of the inlet opening can be set large enough for safe extraction. Preferably, the longitudinal slot is formed between the inner wall of the screen and a flange of the reflector adjacent to the inner wall.

The sealing tube member may be a radiator tube having a variable operating temperature along its length, such as a gas-heated or hot-water heating radiator tube, wherein the at least one longitudinal inlet and / or the subsequent longitudinal slot is varied proportionally to the operating temperature of the heating tube member. and the umbrella may be arranged to be continuously inclined in the direction of flow of the fluid in the fitting member relative to the fitting member. The radiator tube may also have a substantially constant operating temperature along its length, such as a steam or electric heater.

One advantage of utilizing the convection heat dissipated is that the fan transmits the heated air through a duct or directly to the lower part of the space to be photographed.

Preferably, the fan suction and the width of the at least one longitudinal inlet and / or the longitudinal gap thereafter are selected such that the amount of heated air flowing into the space between the reflector and the screen substantially corresponds to the amount of heated air flowing upward. In this way, the flow conditions around the radiator tube are minimized.

The heating tube member may be a substantially straight tube or a U-tube. Optionally, the top surface of the reflector may be covered with heat insulating material.

In the following, exemplary preferred embodiments of the invention will be described by the drawings, wherein:

Figure 1 is a partially exploded schematic diagram of a heating apparatus according to the invention, partially broken away, a

Figure 2 is a schematic cross-sectional view of the embodiment of Figure 1, a

Figures 3 and 4 are enlarged drawings of Part A of Figure 2 showing flow conditions, a

5-7. Figures 1 to 8 are conceptual cross-sectional views of further preferred embodiments of the invention;

Fig. 8 is a schematic side view of a preferred embodiment of a heating pipe member having a variable temperature along its length, and

Figure 9 is a diagram illustrating an air cushion having a thickness compensated by the embodiment of Figure 8.

The heater tube heater shown in Figure 1 comprises a heater tube element 1, which in the embodiment shown is a substantially straight gas heater heater.

The known burner required for gas heating is not shown in the figure. This embodiment is advantageous for ceiling mounting, in which the reflector 2 made of metal sheet to reflect the upward heat radiation emitted by the heating pipe element 1 is arranged substantially symmetrically above the heating pipe element with respect to the vertical symmetry plane passing through the radiation pipe. Above the reflector 2 is placed a screen 4 made of sheet metal. The space between the screen 4 and the reflector 2 is closed by end walls 9 and a fan 5 is connected to the space between the screen 4 and the reflector 2 through an opening in one of the end walls 9. An outlet duct (not shown) may be connected to the outlet port of the fan 5.

The end walls 9 are formed in the embodiment shown in Figure 1 and in other embodiments such that the structure consisting of the reflector 2 and the shade 4 is completely closed from the side at its longitudinal ends. Thus, the air heated by the heater tube element 1 cannot flip upwards at the longitudinal ends of the reflector 2, but only flows into the space between the shield 4 and the reflector 2, as described below.

2 shows that the reflector 2 is formed on each side with a longitudinal edge flange portion 7 which in the preferred embodiment is inclined outwardly and upwardly from the runner element 1. The umbrella 4 also has two longitudinal flange portions 8 on each of its longitudinal sides, extending laterally and downwardly from the respective longitudinal flange portions 7 of the reflector 2, thereby defining a longitudinal suction opening 10 through which air heated by the heater element 1 can flow into the space between the screen 4 and the reflector 2. As shown in the figure, the longitudinal edges 8 of the screen 4 are inclined towards the heating element 1 for proper extraction of the heated air 3. Optionally, the flange portions 8 may be formed inclined towards the heating pipe element 1 and upwards. At this point, the upwardly sloping ends of the flange portions 8 of the screen 4 may act as reflectors, but are considered to be part of the screen 4 according to the invention.

The fan 5 connected to the space between the screen 4 and the reflector 2 can suck the heated air 3 through the air duct 6 to the desired location, for example to a lower part of the space to be exposed to strong cold radiation or draft. Such a part of the space to be run can be, for example, an industrial gate or a wall with large windows. Furthermore, the heated air 3 for heating purposes can be introduced not only into the space to be heated, but also through a suitable air duct, for example, into another room or used in industrial technologies.

Figures 3 and 4 show flow conditions corresponding to two different suction powers of the fan 5. The flow rate V in Fig. 3 is such that the distance H of the boundary layer from the bottom of the flange 7 is exactly the distance between the flange 7 and the lowest points of the flange 8. A relatively small amount of cold air is then introduced into the volumetric flow V; the greater part M of which is formed by the air heated by the heating element 1.

HU 220 805 Bl

In the position shown in Fig. 4, the fan 5 connected to the space between the screen 4 and the reflector 2 produces a volumetric flow V '> V, whereby the distance of the boundary layer is reduced to H'. Significantly more cold air is then introduced into the volumetric flow, i.e., the portion M 'containing the heated air will be smaller, but it will be ensured that the total convection heat generated will be removed and utilized. The situations shown in these two figures may not only be caused by varying the suction power of the fan 5, but also by varying interferences during operation, such as draft effect, change in operating temperature, etc. as well. The self-regulating design of the present invention is particularly advantageous because it is practically insensitive to such disturbing effects that are common and frequent in the runners and, secondly, because the suction of hot air cannot be accurately scaled under practical conditions.

In the preferred embodiments of the heater according to the invention, a longitudinal slot 13 of a width less than its width is formed in the direction of the flow of heated air 3 in the space between the screen 4 and the reflector 2 after the at least one longitudinal suction opening. In this embodiment, this gap 13 is located between the inner wall of the screen 4 and the flange of the reflector 2 adjacent to the inner wall. With this slit 13, the amount of exhaust air can be appropriately controlled, while the width of the inlet 10 can be set large enough for safe extraction. For example, the width of the slots 13 may be 0.5 to 20 mm.

Thus, in the embodiment of the present invention, the boundary layer automatically pulls upward at higher air intake and moves downward at lower air intake. Thus, in both cases, the total amount of convection heat can be removed without reckoning with any cooling of the tread element. The self-regulating design allows for a relatively large change in volume flow or slit width variation of ± 50% relative to the mean value. The suction of the fan 5 and the width of the at least one longitudinal inlet 10 and / or the longitudinal slot 13 thereafter should preferably be chosen such that the amount of heated air 3 entering the space between the reflector 2 and the screen 4 substantially corresponds to the with the amount of heated 3 air flowing upwards. At this point, the flow conditions in the vicinity of the tread element 1 are least affected.

For a better heating efficiency, it is advantageous for the heated air 3 to be collected in the space between the screen 4 and the reflector 2, since this also achieves an insulating effect due to the fact that the surface of the screen 4 is smaller than its reflector 2. the temperature difference between the corresponding surface and the surrounding air is reduced.

The embodiment shown in Fig. 5 is advantageous because of its wall mounting. The reflector 2 and the screen 4 of the heater are rotated about 30 ° around the tread element 1, as a result of which the heater radiates heat to the lower part of the space to be heated, not vertically downwards. In this embodiment, there is no longitudinal suction opening 10 between the lower flange portion 7 of the reflector 2 and the corresponding flange portion 8, but the convection-heated air 3 between the higher portion 7 of the reflector 2 and the corresponding flange portion 8 through a longitudinal suction opening 10 'into the space between the screen 4 and the reflector 2. Preferably, the suction opening 10 'of this embodiment is approximately twice the width of the inlet

2, the width of the inlet opening 10 of the embodiment shown in FIG. In this embodiment, it is expedient to form the edge portion 8 of the screen 4 defining the inlet opening 10 'substantially vertically downwards. The heater can be tilted arbitrarily within the range of 0 to 30 ° according to the desired heating conditions, as in Figure 5.

The embodiment of Fig. 6 differs from that of Fig. 5 in that the collection of the air heated by convection 3 is determined not by a space 4 defined by a screen 4 surrounding the entire reflector 2, but by a screen 11 arranged just above a portion of the reflector 2. in space. In this way, less plate material is required to form the heater. In this embodiment, the upper surface of the reflector 2 is preferably provided with a heat insulating material 12 to reduce the amount of heat transmitted by the reflector 2 to the ambient air.

In the embodiment of Fig. 7, the tread element 1 is a known, U-shaped radius tube, the two arms of which are arranged under a common reflector 2.

Fig. 8 shows a preferred embodiment of the heater according to the invention, in which the operating temperature of the tread element 1 varies along its length. This phenomenon is observed, for example, in gas-heated or hot-water heated truss elements 1, where the operating temperature of the trench element 1 is continuously decreasing in the flow direction of the fluid flowing in the trunk element. In such cases, the thickness of the air cushion for convective purposes, consisting of heated air above the boundary layer, and its rate of formation continuously decreases along the length of the tread member 1 in the direction of flow of the fluid. The utilization of total convection heat can then be achieved, for example, by forming the longitudinal inlet openings 10 and / or the longitudinal slots 13 with a width that is varied along the length of the tread element 1 in proportion to the operating temperature of the tread element. However, it may also be advantageous to have the arrangement shown in Fig. 8, in which the reflector 2 and the umbrella 4 are arranged continuously inclined with respect to the heating element 1 in the direction of the medium flowing in the flow pipe 1. In this case, it is not necessary to change the width of the inlets 10 and / or the longitudinal slots 13, which results in easier manufacturing. Preferably, the degree of α-elevation is about 0.5% to about 3%.

In a heater with an a-pitch reflector 2 and a screen 4, the thickness of the air cushion is equalized along the length of the heater element. This is illustrated in Fig. 9, which shows the thickness Vj at the beginning of the screen 4

EN 220 805 B is a vertically lined air cushion with a thickness of v ₂ and a v ₂ thickness at the end of the 4 screens, which characterizes a heater without rising. The heater with an a-pitch reflector 2 and a screen 4 produces an air cushion of uniform thickness V ₃ . In addition to the uniform inlet and / or slit width, this design has the further advantage that the α-rise affects the temperature distribution of the heater element 1, so that the temperature difference between its start and end points is smaller than the α-rise without design.

If the heating element 1 is, for example, a steam-heated or electrically-heated radiator tube whose operating temperature does not change along its length, or a gas-heated radiant tube with internal insulation, the above solutions are not required.

The heating device according to the invention can, of course, be implemented differently or in combination with the embodiments shown. In the heater according to the invention, it is not necessary to provide a narrowing slot 13 after the inlet openings 10,10 ', but the exhaust of the heated air 3 can also be controlled by the width of the inlet openings 10, 10'. It is possible to place several reflector tubes under a single canopy or to design a wall-mounted inclined heater with an α-rise. It is also possible to place the two legs of the U-shaped radiation tube under separate reflectors, whereby an additional longitudinal suction opening is provided between the two reflectors for the upwardly heated air. The heating element may also be formed in a straight and U-shaped shape.

Claims (15)

A radiant heat and convection heat heater comprising a radiant heat radiator heating element, a reflector having at least a portion of the length of the radiator element and having a longitudinal peripheral portion on each side of the radiator element to receive the radiant heat emitted by the radiator at least a portion of the canopy and a fan connected to the space between the canopy and the reflector for conveying the heated air therein to a desired location, characterized in that the canopy (4,11) has at least one side of the heating element (1) a flange portion (8) defining at least one longitudinal suction opening (10, 10 ') extending laterally and downwardly from the longitudinal flange portion (7) of the reflector (2) between the shield (4, 11) and the reflector (2) fore for upwardly inflated heated air (3), wherein the heated air (3) entering the space between the screen (4, 11) and the reflector (2) is conveyed to the desired location by suction from the space by the fan (5). Heating device according to Claim 1, characterized in that the longitudinal edge flange portions (7) of the reflector (2) are arranged at the same height as the heating pipe element (1), and the lever (4) has on both sides of the running pipe element (1). with a longitudinal peripheral edge portion (8) defining a longitudinal inlet (10). Heating device according to claim 2, characterized in that the longitudinal flange portions (7) of the reflector (2) are formed outwardly and upwardly from the heating element (1) and the longitudinal flange portions (8) of the heater (4) are formed by the heating element (1). ). Heating device according to claim 1, characterized in that one of the longitudinal edge flange portions (7) of the reflector (2) is arranged at a height higher than the heating pipe element (1), wherein the at least one longitudinal inlet (10 ') is (2) is provided at a higher elevation at its longitudinal peripheral edge portion (7). Heating device according to Claim 4, characterized in that the longitudinal edge portion (7) of the reflector (2), which is arranged at a higher height, is formed outwardly and upwards from the heating element (1), laterally and downwardly extending from the heater (4,11). and the peripheral edge portion (8) is inclined downwardly. Heating device according to claim 1, characterized in that in the space between the muzzle (4,11) and the reflector (2) in the direction of upward flow of heated air (3) after at least one longitudinal inlet (10, 10 '). a longitudinal slot (13) having a width less than its width. Heating device according to claim 6, characterized in that the longitudinal slot (13) is located between the inner wall of the muzzle (4, 11) and the flange of the reflector (2) adjacent to the inner wall. Heating device according to Claim 6, characterized in that the heating pipe (1) has a variable operating temperature, such as a gas or hot water heater, and at least one longitudinal inlet (10,10 ') and / or The longitudinal slot (13) is formed along the length of the heating element (1) with a width that is varied in proportion to the operating temperature of the heating element (1). Heating device according to Claim 1, characterized in that the heating tube (1) has a variable temperature operating tube, for example a gas heating or hot water heating tube, and a reflector (2) and a screen (4, 11) in the heating tube (1). 1) arranged in a continuous direction in the direction of flow of the fluid relative to the running member (1). Heating device according to Claim 1, characterized in that the heating pipe element (1) has a constant operating temperature radiator tube, for example a steam-heated or electrically heated radiator pipe. Heating device according to claim 1, characterized in that the fan (5) transmits the heated air (3) through the air channel (6) or directly to the lower part of the space to be heated. Heating device according to Claim 6, characterized in that the suction of the fan (5) and the width of the at least one longitudinal inlet (10,10 ') and / or the subsequent longitudinal slot (13) are chosen such that the amount of heated air (3) entering the space between the reflector (2) and the forehead (4, 11) EN 220 805 Bl ge correspond to the amount of heated air (3) flowing upwards through the reflector (2) without the shade (4, 11). Heating device according to claim 1, characterized in that the heating element (1) is a straight radiator tube. Heating device according to Claim 1, characterized in that the heating pipe element (1) is a radial tube bent in a U-shape. Heating device according to claim 1, characterized in that the reflector (2) is covered with a heat-insulating material (12) on its upper surface.