CS225116B2 - The electric heat storage stove - Google Patents

Abstract

1,241,760. Electric thermal storage stoves. ATELIERS DE CONSTRUCTIONS ELECTRIQUES DE CHARLEROI. 1 May, 1969 [2 May, 1968], No. 22327/69. Heading F4U. An electrically heated thermal storage stove comprises a thermal storage mass 2 having an air duct 9, 11 and a cross-flow fan 14 which draws air through the duct 9, 11, and unheated air through a gap between plates 10, 19 and discharges the mixture through an outlet 17. The bearings of the fan impeller are outside the fan housing and are cooled by a flow of unheated air induced by the airflow through the outlet 17.

Description

The invention relates to electric storage heaters in which air is sucked by a fan 8 transversally through the storage core into a suction chamber, and at the same time having a direct suction air inlet.

The stove of the above type is described in Belgian patent specification No. 673 830. In this solution, the direct supply of cold air to the fan is controlled by a control vane register or flap, the fan being located at the outlet side of the stove. The disadvantage of this solution is, in particular, that the regulation by means of the flap or vane register is too sensitive and the mixing with the warm air depends on the unstable turbulent flow of the air currents which separate from the flap. In addition, positioning the fan near the outlet opening of the stove results in undesirable noise and makes it difficult to dissipate the heating air in the heated room.

These drawbacks eliminate electric storage heaters in which air is sucked by a cross-flow fan through the storage core into a suction chamber having a direct cold air inlet, the suction chamber being defined by an upper guide plate, a rear guide plate and a lower guide plate arranged away from its inlet opening adjacent to the downward branch of the accumulator core passageway to its outlet opening at which the fan is located and which is defined by a leading edge at the outlet end of the lower guide plate and a trailing edge at the front end the upper walls of the fan housing lying behind the front edge in terms of the direction of rotation of the fan, the direct inlet for cold air being formed by an upper non-suction slot opening into the suction chamber above the fan and terminating at the rear edge an outlet port where the suction slot is located above the outlet port of the suction chamber, the outlet port itself being located above the outlet port of the ventilator opening into the outlet duct for the heating air.

In this way, there is a flaring or quasi-miniature flow of the stove, which results in the gradual mixing of the hot and cold air. By cooling down, in principle, the temperature of the mixed air discharges is less dependent on the temperature of the storage core. In principle, the use of a control flap is therefore not necessary. Even where the flap is used, it is less sensitive to its effect and the flap does not act as a disturbing element that would affect this mixing. In a special arrangement in which the outlet opening is located below the cold air inlet to the ventilator, it is additionally achieved that, despite the mixing effect in the ventilator area, an air stream is obtained whose lower layer is slightly cooler than the upper. This reduces the possibility of overheating flammable floor coatings, such as carpets, located near the exit opening of the stove.

According to a preferred embodiment of the invention, the ventilator is located at the rear side of the stove. This increases the noise of the stove, which is dependent on the distance of the fan from the outlet. In addition, this extends the air discharge path and may therefore result in a better mix. ,

According to another feature of the invention, the outlet channel extends from the ventilator towards the outlet opening of the stove. This further improves the aerodynamic parameters of the stove and makes it more efficient to distinguish between the warmer layer at the top of the exiting flow of heating air and the colder layer at the floor.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail in the following description by way of example with reference to the drawings, in which Fig. 1 shows a vertical section through a storage heater according to the invention - and Fig. 2 shows a perspective view of part of these heater. in partial section.

As can be seen from the drawings, the electric storage heater according to the invention uses a sheath X which surrounds the storage core 2. The immunization core 2 is immediately encased by a heat insulating layer 2 and between the heat insulating layer 2 and the sheath lies 6, J and 8, a heated air passage 22 is provided in the storage core 2 with an ascending branch 2 ^{with a} descending branch Ц. The width of the passageway 22 in the longitudinal direction of the stove is slightly smaller than the stove, which results from the construction described above. *

Underneath the downward branch 11 of the passageway 22 is a suction chamber 20 of a ventilator into which air enters from the passageway 22 through an inlet -21. The suction chamber 20 is defined by the guide plates, namely the upper plate 12. a rear guide plate 10 and a lower guide plate X} for directing the heated air to the ventilator 11. The outlet opening 23 of the suction chamber 20 is defined by a leading edge 16 located at the outlet end of the lower guide plate 13 and a trailing edge 15 located at the front end of the top wall 12 of the casing 14.

The length of the vane roller of the fan 14 is approximately as long as the width of the passageway 22, hence the width of the column of air flowing through the stove. As can be seen from the drawings, the ventilator is located along the wall of the stove. The air intake slot 24 'of the air into the suction chamber 20 of the fan 14 is located above the outlet opening 21 of the suction chamber, as shown in Fig. 1, defined by the upper wall 12 of the fan housing 14 and the lower guide plate 13. the suction slot 24 is connected to a common supply of cold air from the surrounding environment, which is formed in particular by an opening 2 or an air outlet. through the aperture 4, through the air movement in the gap 4 ·

Below the outlet opening 23 of the suction chamber 20 is located on the discharge side of the fan 14 a heating air outlet channel 17 into which heating air is blown through the outlet opening 25 of the fan. The outlet channel 17 extends from the outlet opening 25 to the stove outlet opening, as shown in the drawings.

The function of the stoves according to the invention is apparent from the above description and the drawings. By the suction effect of the fan 14, cold air is sucked into the passageway

22. where, by passing the ecre storage core 2, it heats and enters the suction chamber 20 of the fan on the one hand for direct inlet through the suction slot 24 to the fan. The fan 14 rotates clockwise and blows the air mixture into the outlet duct. As a result of the arrangement of the suction chamber outlet opening 23 in the suction slot 24, as described and as shown in the drawing, separation of hot and cold air streams as schematically indicated in FIG. 1 by dashed lines with arrows. Cool air entering directly to the fan

14. is thus predominantly guided in the lower part of the outlet duct tedy, thus along the floor of the heated room, while hot air is pushed rather towards the upper edge of the outlet duct. This achieves the fact that the temperature of the exiting heating air at the floor is maintained at a sufficiently low level to avoid the risk of fire when flammable material, such as carpets, is placed in the vicinity of the stove on the floor. On the other hand, the upper layers of the exiting heating air stream may have a higher temperature.

A particular advantage of the described arrangement of the suction chamber 20 of the fan 14 lies in the fact that some automatic regulation of the temperature of the air blown out during the period in which the electric storage heaters emit accumulated heat. This is in many cases possible without a control damper. The very hot air has a very low density at the beginning of the heat transfer, while at the end of the heat emission, the density of the malfunction coming from the passageway 22 is comparable to the density of the cold air drawn directly from the room.

E

Initially, the sowing effect of the fan 14 is attenuated by the tendency of the hot air to remain in the core of the storage core, the hot air being sucked into the hot air mixture to a lesser extent than at the end of the heat emission period. The amount of warm air sucked in to the cold air gradually increases as the temperature of the storage core 2 decreases. At the beginning of the heat accumulation in the core, the temperature of the air drawn in by the fan is not too high. The heat produced by the storage core 6 is kept at an acceptable level.

The fact that hot air is drawn in through the fan Ie. imposes certain requirements to solve the problem of heating its bearings. Although there are special high temperature bearings, these bearings are expensive. As is apparent from FIG. 2, where the bearings 18 are schematically indicated, the bearings 18 are terminated at a distance from the stone shell so that gaps are formed at the longitudinal ends of the bottom of the stove, through which cold air entrained by air blown by the fan 14 can enter directly This cold air stream, which separates at the opening 8, is indicated in FIG. 2 by a dashed line with an arrow.

In addition, along the bearings 18, there is a vertical air intake of cold air due to the gaps between the bent edge 26 of the fan casing wall 19 and the stove casing. This air is sucked in by the edge blades of the fan. It is clear from both Fig. 1 and Fig. 2 that the mixing with warm air will be less in the region of these separated streams than in the central part of the fan. Without the need for special bearings, cooling of the fan bearings 18 is thus automatically achieved.

Claims (3)

An electric storage heater in which air is sucked by a ventilator in a transverse direction through the storage core into a suction chamber, having at the same time a direct cold air inlet, characterized in that the suction chamber (20) is defined by an upper guide plate (12), a rear guide a plate (10) and a lower guide plate (13) disposed away from its inlet (21) following the downward branch (11) of the through-flow channel (22) of the storage core (2) to its outlet (23), a fan is placed; (14), defined by a leading edge (16) lying at the outlet end of the lower guide plate (13), and a trailing edge (15) located at the front end of the top wall (19) of the fan housing (14) a fan (14) behind the front edge (16), the direct cold air step being formed by an upper suction slot (24) opening into the suction chamber (20) above the fan (14) terminating at the rear edge (15) of the outlet port (23). 1), wherein the suction slot (24) is located above the outlet opening (23) of the suction chamber (20), the outlet opening (23) itself being located above the outlet opening (25) of the fan opening into the heating air outlet duct (17). Electric storage heater according to claim 1, characterized in that the fan (14) is located at the rear wall of the stove. Electric storage heater according to claim 1 or 2, characterized in that the outlet channel (17) extends in the longitudinal profile from the outlet opening (25) of the fan (14) towards the outlet opening (8) of the heating air stove.