FR2897146A1 - Heating system with open fireplace or stove has primary and secondary air flow circuits with turbines to maintain flow - Google Patents

Abstract

The heating system has a frame with a primary circuit (8) for delivering an air flow to the fire, and a secondary circuit (108) with its upper end linked to an ambient air circulation duct and a lower end (130) with room outlets. The primary circuit has at least one turbine driven by outside air, and the secondary circuit has at least one turbine turned by the primary one(s) to force air towards the room outlets. The turbines can be mounted on a common shaft and driven by a single motor.

Description

The present invention relates to a fireplace heater, as well as

  that a method of implementing this heating device.

  Within the meaning of the invention, such a heating device hearth including, but not limited to, an open fireplace, and a stove or wood insert having a closed hearth. The disadvantage of heating devices known from the state of the art lies in the fact that their use is accompanied by a cold air call. It is therefore conceivable that the phenomenon is unpleasant for the occupants of the room, in which is placed the heater.

  That being said, the invention aims to remedy this drawback. It thus aims to provide a fireplace heater, which provides comfort of use more satisfactory than in the prior art. It also aims to provide such a heating device, the structure allows it to adopt different dimensions, so as to adapt to the previously provided heating devices, and quickly and convenient way. For this purpose, it relates to a heating device fireplace, including open fireplace, wood stove or closed fireplace, comprising a frame, a primary circuit, suitable for supplying a fireplace of this fireplace with outside air, a secondary circuit, provided in the vicinity of said focus, said secondary circuit having an upper end in communication with at least one ambient air flow duct, and a lower end opening into a room, the primary circuit being provided with at least one primary turbine capable of being set in motion by the outside air, and the secondary circuit being provided with at least one secondary turbine rotatably connected to the or each primary turbine, the or each secondary turbine being suitable for directing the air present in the secondary circuit towards said lower end, in order to pulsate this air in the room. According to other features of the invention the respective primary and secondary turbines are adapted to be driven by a common drive motor - the secondary circuit comprises a plurality of secondary circuit elements arranged next to each other, each of which is provided with a turbine, said turbines being driven on a common shaft; each secondary element, which has an L shape, has a horizontal part provided under the firebox, which is provided with said lower end, and a vertical part placed against a bottom wall of the frame, which is provided with said end; superior; the primary circuit comprises two primary circuit side elements, each of which is provided with a primary turbine and each of which has a tubular body which is identical to the tubular body of each secondary circuit element; the tubular body of each respectively primary and secondary element is provided with a head, in which is received a corresponding turbine, each head being provided with an orifice, as well as an opening, adapted to be closed in a manner selective by at least one stopper; for each lateral element of primary circuit, said orifice is in communication with an interior volume of an insert, attached to the tubular body, this insert being provided with means for passing air in the direction dc. home; this chimney comprises a temperature probe, placed in communication with the drive motor of said turbines. The subject of the invention is also a method for implementing the heating device as defined above, in which the or each primary turbine and the or each secondary turbine are started when the temperature of the fyker reaches a predetermined value. . According to another characteristic of the invention, the intensity of a call for air generated by the operation of the stack is measured by means of an anemometer, and the driving speed of said turbines is controlled as a function of the intensity of this call of air. The invention will be described below, with reference to the accompanying drawings, given solely by way of non-limiting example, in which: - Figure 1 is a side view, illustrating a chimney according to the invention; Figure 2 is a top view illustrating the chimney of Figure 1; - Figure 3 is a front view, illustrating the fireplace of Figures 1 and 2; FIG. 4 is a cross-sectional view, on a larger scale, illustrating primary and secondary circuit elements belonging to the stack of the preceding figures; - Figure 5 is a longitudinal sectional view illustrating the front end of a primary circuit element belonging to the chimney of the invention; Figure 6 is a longitudinal sectional view, similar to Figure 5, illustrating a secondary circuit element belonging to the chimney of the invention; and FIG. 7 is a diagrammatic view illustrating various elements making it possible to use the chimney according to the invention. The hearth heating device, shown in the accompanying figures, is in this case an open fireplace. However, the invention is also applicable to, inter alia, stoves and wood inserts having a closed hearth. As shown in particular in Figures 1 to 3, the chimney according to the invention comprises first a frame, which consists of a bottom wall 2, a bottom wall 4, and a top wall 6. Two L-shaped primary circuit elements 8 rest on the bottom wall 2 (FIG. 4) as well as against the bottom wall 4. The horizontal portion 81 of each primary element 8 comprises a visible tubular body 10 in particular in Figure 4, and an insert 12, reported above the tubular body 10. In its inner side wall, namely facing the other insert, each insert 12 is hollowed with an opening 14, closed with selectively by an adjustable flap 16. In addition, each insert 12 is provided with studs 18, adapted to abut against a shoulder 11 of the tubular body 10. It will be noted however that these studs 18 and these shoulders 11 define a passage 20, proper to the circulation of the air as we will see in ns what follows. 83 is the corner of each primary element 8, which corresponds to the intersection between its horizontal portion 81 and its vertical portion 82. As shown in Figures 1 to 3, at this corner 83, each primary element 8 is set in communication with a corresponding arrival 22 of outside air. The other end of these arrivals 22, which is not shown in the figures, opens out of the room. Referring to Figure 5, the front end of each primary element 8 forms a head 24, of greater height, in which is received a turbine 26, of a type known per se. The latter is interposed on the flow path of the air from the tubular body 10 to the upper insert 12. For this purpose, an orifice 28 is formed in the rear part of the head 24 while an opening 30, formed on the front portion of this head 24, is closed by a plug 32. It will be noted in this Figure 5, that the blades 27 of the turbine 26 are of bucket type, with a flat surface and a convex surface.

  The chimney according to the invention also comprises a number of secondary circulation elements 108, interposed between the two primary elements 8, which are arranged laterally on either side of these different secondary elements 108. The structure of these elements secondary is similar to that of the primary elements 8. For the sake of clarity, the same mechanical members of the secondary elements 108 will be assigned the same reference numbers as those comprising the primary elements 8, increased by 100.

  Each secondary element 108 comprises a horizontal part 1081, as well as a vertical part 1082. As shown in particular in FIG. 4, each horizontal part consists of a tubular body 110, which is however not surmounted by an insert such as in the case of the primary element 8. The different secondary bodies 110, provided next to each other, are placed above a drawer 34, intended in known manner to receive the ash. Moreover, these different tubular bodies 110 define, at their upper part, the hearth 36 of the chimney, which is associated with an adjustable plate 37, of a type known per se. As shown in Figure 6, each body 110 is provided with a head 124, in which is received a turbine 126, of a type known per se. The blades 127 of the turbine 126 have two concave surfaces, to allow good propulsion of air, sent either by the primary turbine 26, or by the electric assistance system. Unlike the primary body 10, the rear opening 128 is closed by a plug 132, since no insert is provided, while the front opening 130 allows free communication with the interior of the room. As shown in particular in Figure 2, the different secondary elements 108 are separated at their head 124 and their upper end by O-rings 113, shown schematically. This allows the passage of air between the different heads of the secondary elements 108. There is also provided two full joints 115, separating the head 24 of each primary element 8 of the head facing an adjacent secondary element. Consequently, the internal volume of the two primary elements 8 is not put in communication with the internal volume of the different secondary elements 108. As shown in FIGS. 1 and 3, the upper end of the various secondary elements 108 is put into communication . with two ducts 122, called ambient air, which open into the interior volume of the room. It will be noted, however, that the upper end of the two primary elements 8 is provided with a plug 38. In other words, the internal volume of the two primary elements 8 is not put in communication with these ambient air ducts. As shown in particular in FIG. 2, the different turbines 126 are mounted on a transverse extending common shaft 134, which is driven by a motor 136. Moreover, as shown in FIG. the chimney according to the invention uses an anemometer 138, shown schematically, which is for example placed in the vicinity of a door of the house equipped with the chimney according to the invention, in particular on the door of main entrance. This anemometer 138 is connected, by a line 140, with a device 142 for adjusting the speed of rotation of the engine 136. Furthermore, there is provided a temperature probe 144, placed in the hearth, which is also provided. relationship with the motor 136 via a line 146. This probe 144 is further connected by a line 148 to a thermostat 150.

  Finally, there is provided a switch 152, for stopping the motor 136, especially in case of emergency. The use of the chimney described above will now be explained in what follows. First, it is a question of placing a suitable fuel, not shown, in the hearth 36, and then igniting it in order to produce flames. At the same time, the motor 136 is not yet started, so that the turbines 26 and 126 are moved in a passive manner, namely by the air flowing in their vicinity.

  The outside air is admitted by the inlet 22, towards the two primary elements 8. This air flows in the body 10, then in the insert 12 via the turbine 26, thus rotating the latter in the clockwise, according to the dotted arrow f.

  This air then escapes towards the furnace, through the openings 14, then along the passage 20, as well as between the different secondary elements 108. In FIG. 4, the path of the air is materialized by the arrows F. It will be noted that this air is in particular directed towards the hearth 36, so that it can maintain the flames. At the same time, air from the workpiece is sucked into the secondary members 108, through openings 130, along the dotted arrow F1. This leads to turn, in a passive manner, the turbines 126 according to the dotted arrow f. This rotation in the clockwise direction of the turbines 106 is also explained by the fact that, as we have seen previously, the motor 136 is not started. The air thus inspired by the opening before 130, is rejected via the conduits 122. As the operation of the chimney, the temperature increases in the home so that, as soon as the probe 144 has detected that this temperature has exceeded a predetermined value, it induces the start of the motor by the line 146. Note that this threshold temperature can be set via the thermostat 150, associated with the line 148.

  Therefore, the start of the motor 136 leads to a reversal of the direction of rotation of the turbines 26 and 126, which now rotate in the counterclockwise direction, according to the full arrows f '. Under these conditions, the air circulating in the primary body 10 is blown by the turbine 26, in the direction of the insert 12. Furthermore, in each secondary element 108, the rotation of the turbine 126 counterclockwise leads to a reversal of the direction of air circulation. In other words, the air is now discharged into the room, through the openings 130, according to the full arrow F2. Simultaneously, the anemometer 138 measures the intensity of the call for air caused by the operation of the chimney. This anemometer 138 then controls the rotational speed of the motor 136, through the line 140. In other words, the greater the air demand, the more the motor 136 is forced to rotate rapidly, so as to further pulse the air. air from the primary circuit 22, in order to minimize the disadvantages associated with the operation of the chimney. Thus, thanks to the invention, the starting of the motor 136, as soon as the furnace has reached a sufficient temperature, makes it possible to pulsate hot air towards the room, via the front face of the elements. Secondary 108. In addition, the turbines provided in the secondary elements operate at the same speed as those provided in the primary circuit, which allows to drive hot air to the front of the chimney, through the openings 130. allows to oppose the cold air flow generated by the operation of the chimney, which we recall that it provides significant inconvenience for the occupants, in the implementation of the state of the art.

  Furthermore, the invention uses air circulation elements that are essentially identical, which is advantageous in terms of simplicity of implementation. On the other hand, thanks to this measurement, the width of the chimney can be adjusted easily.

  The invention is not limited to the example described and shown. As we have seen above, it finds its application to heating devices, other than an open fireplace. It finds particular application to a stove or wood insert, having a closed fireplace. In this regard, the different air circulation ducts, primary and secondary respectively, can be extended in their upper parts by a return. The latter, which extends substantially horizontally, opens towards the front of the stove or insert, in its upper part.

Claims (10)

  1. A fireplace heating device, in particular an open hearth fireplace, a closed wood stove or stove, comprising a frame (2, 4, 6), a primary circuit (8), capable of supplying a fireplace of that fireplace with external air, a secondary circuit (108) provided in the vicinity of said focal point (36), said secondary circuit having an upper end in communication with at least one ambient air flow duct (122) and a lower end ( 130), opening into a room, the primary circuit (8) being provided with at least one primary turbine (26) able to be set in motion by the outside air, and the secondary circuit (108) being provided with at least one secondary turbine (126) rotatably connected to the or each primary turbine (26), the or each secondary turbine being adapted to direct the air present in the secondary circuit towards said lower end (130), in order to jog this air into the room.   2. Heating device according to claim 1, characterized in that the respective primary (26) and secondary (126) turbines are adapted to be driven by a common drive motor (136).   Heating device according to claim 1 or 2, characterized in that the secondary circuit comprises a plurality of secondary circuit elements (108) arranged next to each other, each of which is provided with a turbine (126), said turbines being mounted on a common shaft (134).   4. Heating device according to claim 3, characterized in that each secondary element (108), which has an L shape, has a horizontal part (1081) provided under the hearth (36), which is provided with said lower end. (130), and a vertical portion 12 placed against a bottom wall (4) of the frame, which is provided with said upper end.   5. Heating device according to any one of claims 2 to 4, characterized in that the primary circuit comprises two lateral elements (8) of primary circuit, each of which is provided with a primary turbine (26) and each of which has a tubular body (10) which is identical to the tubular body (110) of each secondary circuit element (108).   6. Heating device according to claim 5, characterized in that the tubular body (10, 110) of each element respectively primary (8) and secondary (108) is provided with a head (24, 124), in which is received a corresponding turbine (26, 126), each head being provided with an orifice (28, 128), as well as an opening (30, 130), adapted to be selectively closed off by at least one plug (32, 132).   7. Heating device according to claim 6, characterized in that, for each side element of primary circuit (8), said orifice (28) is in communication with an interior volume of an insert (12), attached to the body tubular (10), this insert (12) being provided with means (14) for passage of air towards the hearth (36).   8. Heating device according to any one of the preceding claims, characterized in that the chimney comprises a temperature sensor (144) placed in communication with the motor (136) for driving said turbines (26, 126).   9. A method of operating the hearth heating device according to any one of the preceding claims, wherein the or each primary turbine (26) and the or each secondary turbine (126) is operated when the temperature of the hearth (36) reaches a predetermined value.   10. Method according to claim 9, characterized in that by means of an anemometer (138) the intensity of a call for air generated by the operation of the chimney, and the driving speed is controlled said turbines (26, 126) as a function of the intensity of this air intake.