CZ304473B6 - Convector heating element with thermoelectric power source - Google Patents

Abstract

The present invention relates to a convector-heating element with thermoelectric power consisting of a case accommodating at least a heat-exchange apparatus adapted for internal through flow of a heating medium and for greater circulation of a heated air. In the case, there are mounted electric appliances such as at least a fan with an electric drive or further electric or electronic control mechanism of the heating medium and/or the heated air through flow, and/or an electronic device adapted for remote wired or wireless communication with a programmable and/or thermostatic device. Further, the convector warm water hearing element also houses at least one Peltier element having its first active surface adapted for being heated by a heating medium entering the heat-exchange apparatus, and having its second active surface adapted for being cooled by air entering the convector. The invention is characterized in that the first active surface (131) of the Peltier element (13) is connected through a heat-conducting connection (1310) to a flat through flow body (130) adapted for the heating medium flow from the heating medium place of entry (1110) to the convector and/or from an access piping (111) of the heating medium supply to the heat-exchange apparatus (11), and mounted in the convector case (10), while the second active surface (132) is connected through a second heat-conducting connection (1320) to a cooler (14), performed as a plate (140) with ribs (141) projection into the space of air entry into the convector in the direction to of the air flow, wherein at the same time the output electrical terminals (15) of the Peltier element (13) are connected to the electric appliances housed in the convector case (10), and namely at least the electric drive (121) of the fan (12), whereby a system of tubes (1111) is mounted in the flat through flow body (130). Said system of tubes (1111) is performed a loop with entry and exit on one side of the flat through flow body (130), and namely on the side nearer to the heat-exchange apparatus (11) inlet (1112). At the same time the inlet portion of the system of tubes (1111) performed as a loop, is located in said flat through flow body (130) nearer to the longitudinal axis of that said flat through flow body (130) is compared with the location of the outlet portion of the system of tubes (1111) performed as a loop.

Description

Convector heater with thermoelectric power source

Technical field

The invention relates to convector heaters, or convectors, which are designed as heat exchangers, for example hot-water heat exchangers, installed generally in a central heating system of buildings, where the heat transfer takes place from a heating medium passing through the exchanger. with the aid of heated air flow by means of a fan. These are convectors where the fan is equipped with a motor drive, working with electric power. The subject of the invention are convectors, which are built into walls, floors or furniture, where a thermoelectric power source, especially electric energy, is installed directly in the convector.

BACKGROUND OF THE INVENTION

Currently, convectors of many kinds, shapes and designs are known. There are also known many variants of convectors adapted for installation in walls, floors or furniture elements, resp. into gaps, spaces or openings in various pieces of furniture. These convectors are adapted to transfer heat, so that air flows around the heat exchange surfaces of the exchanger, where this air flow can be supported by a fan. Such fans are in most known embodiments driven by electric motors. The described embodiment then requires connection to an electrical power source, which in most known embodiments is realized by connection to a conventional low voltage distribution network, which is usually available in interiors. Neither power input is required too strong and so the device is not demanding from the economic point of view, both the price of consumed electricity and the price of the actual construction of the drive. However, the disadvantage of the above-mentioned embodiments is the necessity to technically create the power supply to the convector, ie to install wires, to connect these on one side to the distribution network, including the necessary circuit breakers, sockets, disconnectors, etc., and to connect these wires on the other , respectively. to the convector case, and inside the convector then follow the internal installation of the whole convector. This is often followed by a control connection to the external control elements of the convector, which is again carried out by wire connections. If the convector is currently connected to the central house control by means of wireless communication, then here too, however, it is necessary to connect the convector to the source of electricity, usually again by means of connection to a common distribution network. With regard to the solution of this problem, i.e. the independence of a device from the external power supply, for example, an embodiment is known according to DE 3106742, wherein the heated air fan in the convector is driven by a turbine whose actuator is installed in the heating fluid flow. Here, while independence from the wired long-distance power supply is achieved, a certain disadvantage is both the mechanical vulnerability and the limited life of such a turbine and its very low performance. Also, the durability and reliability of the described turbine device will be problematic, especially with regard to the design of the shaft seal. In the event of a longer outage, ie always outside the heating season, the gasket will also tend to stick together the movable and solid parts, which will then not move relative to each other without external intervention when trying to start operation at the beginning of the next heating season. Ventilation devices powered from independent sources, such as batteries, etc. are generally known. In addition, devices are known where thermal energy is available as an energy source, where thermoelectric cells, usually so-called Peltier cells, are used to provide electrical power, which operate as generators with the direct conversion of thermal energy into electrical energy. Such sources themselves have been known for a long time and their installation has been carried out in connection with the generation of electrical energy for very low demand devices. For example, a kerosene or gasoline lamp is used as a heat source for the Peltier cells to power the transistor radio receiver as shown in WO 0008692. In another known device, it is the power supply of the electrical device for transmitting the location information of the electrical device as can be seen from

JP 2004274982, wherein the heat source is a transformer and the electric power generator is a Peltier cell. It is even known the device described in JP 2001336780, where a heating or cooling device with thermal energy storage uses a Peltier cell as a source of heat and cold, and also as a source of electric power for operation without an external source for a certain period of time. The ventilator at the time when the accumulation vessels are not charged by heat and cold through the Peltier cells. However, even in the latter embodiments, the convector equipment which meets all the requirements for electric power supply, especially in the case of a convector type, for example a hot water, with a fan, is not solved comprehensively. transfer to the heated space, but at the same time that the regulation is adapted for secondary intervention by another local or remote control element, while the power system of such a convector should be permanently independent of the mains supply while ensuring full operation. The latter requirements are largely met by the apparatus described in CZ U 16627, which addresses a convector arrangement with an electric fan and wherein the source of electrical energy is a Peltier cell, the first active surface of which is connected by a thermally conductive connection to at least one of the connecting tubes. the heating medium entering the heat exchanger or the heating medium leaving the heat exchanger, the second active surface of the Peltier element being connected, for example, by a thermally conductive connection to a cooler housed in the convector housing, preferably at the air inlet to the convector housing. Such an arrangement largely solves the demands placed on hot-water convectors with forced flow of heated air, but in the described arrangement it is in practice only suitable for heating systems where the heating medium circulates at a temperature of about 50 ° C or higher. If electrical energy is to be generated to drive an electric fan during periods with low heating demand, or if the convector is to be connected to a heating system operating in principle with a low heating medium temperature, the temperature gradient for the Peltier is not sufficient and thus does not generate enough electric power for electric fan drive motor. Placing the Peltier element directly on the heat exchanger connection tube does not provide sufficient heat transfer area, and the size of a conventional connection tube is also insufficient to connect a plurality of Peltier cells. The larger interconnection area of the Peltier cells, with a plurality of them, can be connected to a conventional connection tube by means of a suitably shaped conductive joint or thermal bridge, but in connection with a conventional connection tube such a thermally conductive connection will have a long path of heat conduction. a part of the original temperature gradient will not be used, or such a thermally conductive joint will be too complicated, expensive and possibly failing if it is designed, for example, on the principle of an additional heat exchanger with its own microcirculation or heat pipes.

SUMMARY OF THE INVENTION

These disadvantages of the prior art systems of the kind described are reduced, and a heating unit operating without the need for connection to an external electrical distribution network, possibly also for low-temperature heating systems, is obtained from a convector heater with a thermoelectric power source. at least a heat exchanger arranged for the internal flow of the heating medium and for the external bypass of the heated air and in which the electrical appliances are stored, at least an electric fan, or else an electric or electronic flow control device for the heating medium and / or the heated air; and / or an electronic device adapted for long-distance wired or wireless communication with a programming and / or thermostatic device, and further comprising at least one Peltier element in the housing of the convector hot-water heater. the active surface is adapted to be heated by a heating medium entering the heat exchanger, and the second active surface is adapted to be cooled by the air entering the convector according to the present invention, and wherein the first active surface is connected by a thermally conductive a connection to a flat flow body adapted for flow of the heating medium brought here from the point of entry of the heating medium into the convector and / or the heat exchanger and housed in the convector body while the other active surface is connected by a thermally conductive connection to the radiator formed as a plate with protruding ribs placed in the convector's air intake area in the direction of the air flow, and at the same time the output electrical outlets of the Peltier cell are connected to electrical appliances housed in the housing, but at least with electric fan drive, wherein a plurality of tubes formed as a loop with an inlet and an outlet on one side of the flat flow body are disposed in the aforementioned flat flow body, on the side closer to the heat exchanger inlet and at the same time The flow body is located closer to the longitudinal axis of the flat flow body than the outlet portion of the loop assembly.

It is still advantageous if at least a portion of the free outer surface of the flat flow body is provided with a thermal insulation layer. Advantageously, the tube assembly is mounted longitudinally into the longitudinal bores or longitudinal recesses of the aluminum plate, is connected on its inlet side to the heating medium inlet to the convector and on its outlet side to the heat exchanger inlet, the Peltier element being active. The surface to be heated is fixed to the aluminum plate by a flexible adhesive sealant. Alternatively, it is advantageous if the flat flow body is formed as an aluminum plate into which a longitudinal bore or longitudinal recesses are arranged in a longitudinal direction, which is connected for parallel flow of the heating medium in relation to the flow through the exchanger, such that is connected by its input to the place of heating medium entry into the convector and by its output to the output from the convector. Preferably, the cooler is formed as an extruded aluminum profile with a planar base plate and with perpendicularly extending ribs, which taper and / or thinner away from the planar base plate. Alternatively, it is preferred that the heatsink is formed as a sheet or plate planar foundation with attached ribs formed of aluminum sheet. Preferably, the cooler is attached to the surface of the Peltier cell to be cooled by adhering with an adhesive elastic sealant. Advantageously, the Peltier element with the connected flat flow body and the connected radiator is arranged parallel to the heat exchanger and, in terms of air flow through the convector, is placed upstream of the fan. It is furthermore advantageous if a solar cell battery, connected as a parallel source, is provided in the connection of the Peltier cell to the electrical consumers. It is also advantageous if an accumulator battery is connected in the connection of the Peltier cell to the electrical appliances, connected as a backup source. Regarding the overall arrangement used here, with heating of the Peltier element with the supplied heating medium and with air cooling entering the convector, a multiple positive feedback effect is obtained in relation to the temperature of the exchanger of the incoming heating medium or the heat exchanger. between the magnitude of the difference in temperature of the incoming and outgoing heating medium, i.e. between the thermal energy supplied by the heating medium and the requirement to increase the intensity of heat transfer to the heated air with increasing temperature at the inlet to the heat exchanger. With a higher temperature difference, the Peltier element delivers more electrical energy, thereby increasing the fan output, which also increases the cooling of the cooler and thus also cools the second active surface of the Peltier cell, thereby increasing the cooling performance of the fan. thus increasing the temperature difference between the first and second active surfaces of the Peltier cell and thereby further increasing the amount of energy supplied by the Peltier cell, etc., while also improving the heat recovery from the second active surface of the Peltier. This is in favor of further increasing the temperature of the heated air. Yet another advantage is that as an electronic device adapted for remote wireless communication with a programming and thermostatic device, an electronic device is provided as an electronic control unit, mounted on the connecting pipe of the heating medium supply to the exchanger, comprising a flow control servo valve and a first auxiliary active surface of the auxiliary Peltier element adapted to be connected to the first auxiliary heat-conducting connection to the heating medium supply pipe of the heat exchanger, wherein a second auxiliary active surface of the same auxiliary Peltier element is cooled by the second auxiliary heat-conducting connection a connecting pipe of the heating medium outlet from the heat exchanger, the electronic device being at least interconnected

With electric fan drive. In any case, it is also advantageous if at least one temperature sensor is arranged and arranged for sensing the temperature of the heating medium on the connecting line of the heating medium inlet to the heat exchanger to be connected to an electronic device adapted for remote wired or wireless communication with the programming and thermostatic device. and / or on the connecting pipe of the heating medium outlet from the heat exchanger. This may help to more proportionally regulate and / or monitor the operation of the entire heating system or of the individual heating element. Finally, it may be advantageous if the electrical outlets of the auxiliary Peltier element are connected to the temperature difference measuring device between the connecting pipes of the inlet and outlet of the heating medium. By this modification, where a further Peltier element can be optionally included, or preferably an already existing auxiliary Peltier element in the measuring circuit is utilized by a suitable connection, which is commonly created by a specialist in electronics, it is possible to monitor the temperature difference between the heating medium inlet and at the outlet of the exchanger, which provides data to improve the control of the heating system, as well as information about the instantaneous state of functionality of the respective heater in the system. If necessary, the heat input of the respective convector can also be monitored in conjunction with the flow rate.

This achieves an overall unit capable of autonomous operation, including the operation of the fan and any other electrical appliances for regulating the unit, without having to be connected to a mains power source. The consequent advantage is that such a unit can only be mounted on the heating medium inlet and outlet, without the need for further electrical installation work and material. At the same time, such a heating unit can operate without an external source of electrical energy even at a relatively low inlet temperature of the heating medium.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is further described and explained in more detail with reference to the accompanying drawings, in which: Figure 1 schematically illustrates a simple embodiment of a convector body with a Peltier cell connected directly to a fan; Fig. 3 schematically shows an embodiment with an exchanger flow controller and indicated remote data transmission.

DETAILED DESCRIPTION OF THE INVENTION

The heating unit in the exemplary embodiment is constructed as a convector, i.e. a device adapted to transfer heat to the heated space by a flowing medium, which is usually air. Such a convector here consists of a housing 10, in which a heat exchanger 11 is arranged with connection pipes 111, 112 of the heat transfer medium supply and discharge to and from the heat transfer medium. from the heat exchanger 11. The heat exchanger 11 is provided for the internal flow of the heating medium, here the water, and for the external bypassing of the heated air, with the electrical appliances housed in the convector housing 10, in this simple embodiment only the electric fan 12 with electric drive 121. If the term Peltier is mentioned here, then it may be one or more cells, in practice it will always be a battery of such cells, since it is necessary to obtain electrical power that a single cell cannot normally provide. The first active surface 131 of the Peltier element 13 is connected by a first thermally conductive joint 1310 to a flat flow body 130 adapted to flow the heating medium supplied from the heating medium entry point 1110 to the convector and housed in the convector housing 10. The second active surface 132 of the Peltier cell 13 is connected by a second thermally conductive joint 1320 to a cooler 14 formed here as a plate 140 with protruding ribs 141 positioned in the convector's air intake area in the air flow direction. The cooler 14 is connected to the surface of the Peltier cell 13 to be cooled, i.e. the second active surface 132, by gluing with a sticky elastic sealant, which serves here as a second thermal conductor 1320. The output electrical outlets 15 of the Peltier 1 and 2, in the exemplary embodiment of Figs. 1 and 2, the consumer is an electric drive 121 of the fan 12. Preferably, the flat flow body 130 is formed as an aluminum plate into which it is mounted in the longitudinal direction. a longitudinal recess 1111, a pipe assembly 1111 connected at its inlet to the convector's inlet 1110 and at its outlet to the heat exchanger inlet 1112, and to this aluminum plate is a flexible adhesive sealant used here as the first thermally conductive joint 1310, attached Peltiérův article 13, and its pl Alternatively, it may sometimes be advantageous if the tube assembly 1111 in the flat flow body 130 is connected for parallel flow of the heating medium relative to the flow through the exchanger 11 by being connected through its inlet. to the point 1110 of the convector inlet and its outlet to the convector outlet. Such an embodiment, not shown here, will be advantageous, for example, if the convector will often operate with a limited flow rate of the heat transfer medium and the serial flow through the flat flow body would be insufficient to supply energy to the Peltier cell at a low total flow. The flat flow body 130 itself, in the illustrated embodiment, is then formed as follows. The flat flow body 130 houses a set of tubes 1111 formed as a loop with an inlet and an outlet on one side of the flat flow body 130, on the side closer to the inlet 1112 of the heat exchanger 11. In such a case, it is preferred that the inlet portion of the loop in the flat flow body 130 is located closer to the longitudinal axis of the flat flow body 130 than the outlet portion of the loop. Here, a portion of the free outer surface 1300 of the flat flow body 130 is still provided with a thermal insulation layer 1301. Preferably, the cooler 14 is here formed as an extruded aluminum profile with a planar base plate 140 and ribs 141 projecting perpendicularly, which thinner away from the base plate. Alternatively, the cooler can also be designed as a strip or plate planar foundation with attached ribs made of aluminum sheet. Such an embodiment is not shown here, but in general one of said alternatives would be chosen according to the particular shape requirement and the expected size of the series in production. The Peltier element 13 with the connected flat flow body 130 and the connected radiator 14 is arranged therein parallel to the heat exchanger 11 and, in terms of air flow through the convector, is placed upstream of the fan 12. Following this arrangement and in relation to the structure described above, the active surface 132 of the Peltier cell 13 is connected to a cooler 14, here designed just as an air cooler, located at the location of the heated air stream in the convector housing 10, such that the air cooler is housed in the housing W in relation to the fan arrangement 12; As a result of the fact that it is located at the point of entry of a substantial part of the air into the fan 12, a multiple positive feedback effect is obtained in relation to the temperature of the exchanger of the incoming heating medium or the heat exchanger. between the magnitude of the difference in temperature of the incoming and outgoing heating medium, and the energy generated by the Peltier element, as described above. At the same time, the output electrical outlets 15 of the Peltier cell 13 are connected to the electrical appliances housed in the convector housing 10, but at least to the electric drive 121 of the fan 12, as is the case in FIG. a solar cell battery connected as a parallel source can also be included in the appliance. Such an embodiment is also not shown here, but it is a parallel connection of such cells which, when the convector is idle, for example outside the heating season, can easily rotate the fan 12 and prevent stiffness in the bearings. A battery pack, which is connected as a back-up source, can be recharged by electric appliances. The solar cells can recharge the battery. In another version of the apparatus shown in FIG. 3, an electronic device 16 is provided for remote wireless communication with the programming and thermostatic device, in the form of an electronic control unit, mounted on the connecting line 111 of the heating medium supply to the heat exchanger 11. comprising a flow control servo valve and also comprising further auxiliary active surfaces 131a, 132a of another, auxiliary Peltier element 13a, provided, in the case of the first further, first auxiliary active surface 131a, to be mounted on the connecting line 111 of the heating medium supply to the exchanger Π. and, in the case of a further, second auxiliary active surface 132a, adapted to be coupled by a further, second auxiliary heat seal 1320a to the connecting line 112 of the heating medium outlet from the heat exchanger 11. The electronic one

The control unit is connected to the electric drive 121 of the fan 12 and is further connected to a room thermostat (not shown here) by remote transmission. At the same time, the electronic unit, respectively. the electronic device 16 may also be another consumer connected to the Peltier cell 13, here via an electric drive 121. For better control, it may also be advantageous if the electronic device adapted for remote wired or wireless communication with the programming and thermostatic device is at least one temperature sensor is provided and arranged to sense the temperature of the heating medium on the connecting line of the heating medium supply to the heat exchanger and / or on the connecting line of the heating medium outlet from the heat exchanger. This may help to more proportionally regulate and / or monitor the operation of the entire heating system or even of the individual heating element. Such a device as a whole is not shown here, but one skilled in the art of thermo-regulation can create such a device in specific schemes. As a source of information on the temperature difference of the heating medium at the inlet and outlet of the convector there is useful auxiliary Peltier element 13a, which here partially fulfills the function of temperature sensors at said inlet and outlet, respectively. function of the temperature difference sensor.

This achieves an overall unit capable of autonomous operation, including the operation of the fan and any other electrical appliances for regulating the unit, without the need to be connected to a mains power source. The consequent advantage is that such a unit can only be mounted on the heating medium inlet and outlet, without the need for further electrical installation work and material. In particular, it is advantageous to operate the described convector even in heating systems with a low temperature of the heating medium.

Industrial applicability

The device according to the present invention can be used as a heater, particularly for interiors, in situations where high heating efficiency is required with minimum space requirements and minimum assembly and installation work. The minimization of assembly work is a benefit of the full autonomy of the heater in relation to the electrical power requirement, so that a convector heater is provided which does not require any electrical interconnectors for installation and does not need to be electrically connected to an external source using electrical wires, since the source for the actual production of electric energy is the thermal energy supplied to the body as a heated heating medium. From the point of view of possible applicability it is necessary to say that the device is fully analogous applicable also for air cooling, instead of its heating, where the heating water or other medium will then be a cooling medium. active boards of Peltier cells and adequately connected and adjusted regulation and control elements.

Claims (13)

PATENT CLAIMS 1. A convector heater having a thermoelectric power source, consisting of a housing in which at least a heat exchanger is arranged, adapted for the internal flow of the heating medium and for the external flow of heated air, and in which the electrical appliances are stored, at least an electric fan; also electric or electronic heating medium and / or heated air flow control device and / or electronic device adapted for remote wired or wireless communication with a programming and / or thermostatic device, and further comprising at least one Peltier heating element in the convector hot water heater housing a cell having a first active surface adapted to be heated by a heating medium entering the heat exchanger, and a second active surface adapted to be cooled by air entering the convector, characterized in that, in the case of a Peltier cell (13), the first active surface (131) is connected by a thermally conductive joint (1310) to a flat flow body (130) adapted to flow the heating medium supplied from the heating medium inlet (1110) to the convector and / or from the heating medium supply pipe (111) to the heat exchanger (11) and housed in the convector housing (10), while the second active surface (132) is connected by a second thermally conductive joint (1320) to a cooler (14) formed as a plate (140) with projecting fins (141) The outlet electrical outlets (15) of the Peltier cell (13) are connected to electrical appliances housed in the convector housing (10), at least with an electric drive (121). a fan (12), wherein a flat flow body (130) houses a set of tubes (1111) formed as a loop with an inlet and an outlet on one of the early flow flat body (130) on the side closer to the inlet (1112) of the heat exchanger (11) and at the same time the inlet portion of the tube assembly (1111) formed as a loop is positioned closer to the longitudinal flow body (130). axis of the flat flow body (130) before the outlet portion of the tube assembly (1111) is formed as a loop. Convector heater according to claim 1, characterized in that at least a portion of the free outer surface (1300) of the flat flow body (130) is provided with a thermal insulation layer (1301). A convector heater according to claim 1 or 2, characterized in that the tube assembly (1111) is mounted longitudinally into the longitudinal bores or longitudinal depressions of the aluminum plate, is connected at its inlet side to the heating medium inlet (1110) into the and at its outlet side at the inlet (1112) of the heat exchanger (11), the Peltier element (13) with its first active surface (131) to be heated, attached to the aluminum plate by a flexible adhesive sealant. A convector heater according to claim 1 or 2, characterized in that the flat flow body (130) is formed as an aluminum plate into which a longitudinal bore or longitudinal recesses of the tube assembly (1111) is connected in the longitudinal direction. for parallel flow of the heating medium in relation to the flow through the heat exchanger (11) by being connected by its inlet (1110) to the heating medium inlet to the convector and by its outlet to the connecting pipe (112) of the heating medium outlet ) heat. Convector heater according to one of Claims 1 to 4, characterized in that the heatsink (14) is designed as an extruded aluminum profile with a planar base plate (140) and ribs (141) projecting perpendicularly and tapering away from the planar base plate (140). / or reduce. Convector heater according to claims 1 to 4, characterized in that the cooler (14) is designed as a strip or plate-like planar base (140) with attached fins (141) made of aluminum sheet. 7. A convector heater according to claim 1, characterized in that the heatsink (14) is connected to the second surface (132) of the Peltier element (13) to be cooled by gluing with an adhesive elastic sealant. Convector heater according to claims 1 to 7, characterized in that the Peltier element (13) with the connected flat flow element (130) and the connected radiator (14) is arranged parallel to the heat exchanger (11) and, in terms of air flow through the convector, is located in front of the fan (12). -7EN 304473 B6 Convector heater according to claims 1 to 8, characterized in that a solar cell battery connected as a parallel source is connected in the connection of the Peltier cell (13) to the electrical consumers. 10. A convector heater according to claims 1 to 9, characterized in that an accumulator battery is connected in the connection of the Peltier element (13) to the electrical appliances connected as a backup source. Convector heater according to claims 1 to 10, characterized in that an electronic device (16) designed as an electronic control unit mounted on the supply connection pipe (111) is used as an electronic device adapted for remote wireless communication with the programming and thermostatic device. heating medium to a heat exchanger (11) comprising a flow control servo valve and also comprising a first auxiliary active surface (131a) of the auxiliary Peltier element (13a), adapted to be connected by a first auxiliary thermally conductive joint (1310a) to the connecting pipe (111) a heating medium supply to the heat exchanger (11), wherein the second auxiliary active surface (132a) of the same auxiliary Peltier element (13a) is connected to the heating medium drain connection pipe (112) by a second auxiliary thermally conductive joint (1320a) the heat exchanger (11); This electronic device (16) is connected at least with the electric drive (121) of the fan (12). A convector heater according to claim 11, characterized in that at least one temperature sensor arranged and arranged for sensing the temperature of the heating medium on the connection means is connected to an electronic device (16) adapted for remote wired or wireless communication with a programming and thermostatic device. a pipe (111) for supplying the heating medium to the heat exchanger (11) and / or at the connecting pipe (112) for removing the heating medium from the heat exchanger (11). Convector heater according to claim 12, characterized in that the electrical outlets of the auxiliary Peltier element (13a) are connected to a temperature difference measuring device between the inlet pipe (111) and the outlet pipe (112) of the heating medium outlet from and to the heating medium. into the heat exchanger (11).