ES2469769B1 - Enhanced infrared radiant panel - Google Patents

Abstract

Enhanced infrared radiant panel (1), of the type comprising a circuit (2) of resistive wire associated with a plate (3) of material with high emissivity coefficient so that a transfer of energy from the circuit (2) occurs towards the plate (3), which emits it in the form of infrared radiation; characterized in that it additionally comprises: at least one refractory layer (4) of thermal inertia, at least one layer composed of a power factor compensation capacitor (5), and a power switching controller (6).

Description

Object of the Invention

The present invention relates to an improved infrared radiant panel.

Background of the invention

At present, infrared radiant panels are known which comprise a resistive wire circuit associated with a plate of material with a high emissivity coefficient, so that thermal energy is transferred from the circuit to the pl here, which at in turn it emits it in the form of infrared radiation.

The advantage of this type of panels is that they heat users directly by the infrared radiation they receive on their skin, analogously to the way the sun does, so it is not necessary to heat the air in the room where they are located , such as conventional radiators that work by convection or air conditioning equipment. This results in a better use of energy, since it is transmitted directly to the user, rather than through an intermediary such as air.

These panels have the disadvantage their low thermal inertia, given by the high emissivity itself, so that if they work in all or nothing mode they provide a low comfort of use, because in the disconnection cycles the user does not receive energy or heat at all, while in the connection cycles the energy they receive can

be excessive On the other hand, the incorporation of systems

Current regulation is expensive, which is why

which finally these panels usually work in all mode

or nothing, with little comfort making frequent 5 connections and disconnections.

Description of the invention

The radiant infrared panel of the invention

10 has a constitution that allows to provide a thermal inertia capable of stabilizing the infrared emission at intermediate values to the operation in all or nothing mode.

In addition, it incorporates additional means that provide a better use of the power supply.

According to the invention, the panel comprises a resistive wire circuit associated with a material plate with high emissivity coefficient, or emitter plate, of

20 so that a transfer of energy from the electrical circuit to the board takes place, which emits it in the form of infrared radiation.

The invention has provided for the addition of at least one

25 refractory layer of thermal inertia, so that part of the electrical energy that circulates through the circuit is stored in the refractory layer as heat, so that the greater thermal inertia of the same prevents sudden cooling of the emitter plate and by both a

30 more flat infrared radiation generation curve, avoiding saw teeth typical of all or nothing operations, and enabling intermediate regulations.

Additionally, the invention has provided for the incorporation of another layer composed of at least one

power factor compensation capacitor, and a power switching controller.

The use of the capacitor has resulted in an unexpected heating effect, produced by reactive energy since its resistivity operating in switching is zero, which is intended to be used to cooperate in the thermal accumulation in the refractory layer, and finally in the emission infrared, which is why a flat configuration of the capacitor is preferred, and formally substantially coincident with the shape of the refractory layer, which in turn is preferred to have a shape and dimensions substantially coincident with those of the emitter plate, and that the refractory layer is adjacent to the emitter plate on the inside of the panel, that is, on the opposite side of the panel to which the radiation emits, and that the capacitor is equally adjacent to the refractory layer on the inside of the panel, that is to say its opposite side to that adjacent to the emitter board. It is also possible to use substances that improve thermal exchanges between all these elements.

In this way three beneficial effects are achieved: the intermediate regulation of the infrared emission without any or all fluctuations, a better energy efficiency, taking advantage of the reactive energy, and the compensation of the power factor of the receiving installation

In this document as a high coefficient of emissivity, coefficients preferably greater than 0, 6 are indicated, and more preferred the closer they are to the value 1, although it will depend on the estimation of manufacturing costs, physicochemical properties of the material and performance obtained, being able to lower coefficients become valid if it is profitable from the point

in view of manufacturing costs, or if a material with a lower coefficient is more resistant to the environment of use. Even the invention contemplates the provision of outer layers of material that improves emissivity

5 of the set, and that can cooperate in the protection of the panel itself.

Brief Description of the Drawings

Figure 1 shows a sectional view of the panel of the invention.

Figure 2 shows a detail of Figure 1, where the assembly of a lamp through a multifunction frame is shown enlarged.

Figure 3 shows an exploded view of the panel of the invention.

Figure 4 shows a view of the use of the panel of the invention.

Figure 5 shows a block diagram of the panel controller of the invention.

25 Figure 6 shows a detailed sectional view of the panel, where a variant of the multifunction frame with embellishment sector is seen.

Description of the Preferred Embodiment

The infrared radiant panel (1) of the invention comprises a circuit (2) of resistive wire associated with a plate (3) of material with high emissivity coefficient, so that a transfer of energy from

35 the circuit (2) towards the plate (3), which emits it in the form of infrared radiation, and to which a refractory layer (4) of thermal inertia adjacent to the plate (3) has been added inside the plate panel (1), which in this non-limiting example of the invention contains the circuit

(2) ; another layer composed of a capacitor (5) compensation plane of the power factor adjacent to the refractory layer (4) inside the panel, and a controller

(6) of power switching.

With this configuration the refractory layer (4) provides a thermal inertia that improves the regulation of the operation of the device, alleviating the effects of all or none of the current panels, since it is capable of maintaining a substantially flat temperature curve in the plate (3) regardless of the circuit connections / disconnections (2), precisely minimizing said connections and disconnections.

By adding the capacitor (5), a Re network is configured that can compensate for the power factor of a receiving installation that has other loads - in addition to the panels (1) - that produce an inductive decompensation of the power factor, with the advantage added that it takes advantage of the reactive energy, which produces a heating of the condenser (5) that is transferred to the refractory layer (4) and to the plate (3), finally increasing the infrared radiation and the overall performance of the panel (1).

In this preferred variant of the invention, the panel

(1) various elements capable of controlling its operation in detail are added. For example, a temperature sensor (7) associated with the controller is added

(6), so that it cooperates with the controller (6) in determining the connections and disconnections of the circuit (2).

Thanks to the refractory layer, a stable temperature can be achieved in the layer (3), higher if more infrared emission is required, or lower otherwise, increasing comfort during use. Therefore, the sensor 5 (7) is preferred to be adjustable, that is, to be able to regulably set the detection temperature (thermostat). Substitute or in addition it can be a thermocouple that controls the surface temperature of the plate. In the figures, the sensor (7) has been shown in

10 its thermocouple variant, although the thermostat can be implemented for example in the remote control (6aa) that will be described later.

To optimize the infrared emission and the

15 using energy, the plate (3) can also incorporate an outer layer (8) of high emissivity, with a higher coefficient of emissivity than the plate itself. Said outer layer (8) may incorporate protective compounds of the plate (3) against agents such as the

20 humidity, etc. For example, you can incorporate an antibacterial layer of paint with nano silver.

To concentrate all the temperature generated by the circuit (2) and condenser (5) -and stored in the refractory layer 25 (4) -to the plate (3), the invention has provided for the optional incorporation of an insulating layer (9) thermal envelope, for example of rock wool or the like, which affects the entire panel except, logically, of the part where the radiant plate (3) is located. In addition, with the same purpose and placement, a reflective layer (10), which constitutes a barrier against perimeter infrared loss, can be added, complementary or substitute to the previous one. In the variant of the invention shown in the figures, both layers (9, 10) are incorporated, the insulating layer being

(9) on the inside, that is, further away from the radiant plate (3), and the reflective layer (10) on the outside, its position being equally reversed.

In order to increase the functionality of the panel (1) I, it is provided that its mounting means -objects on the other hand may comprise a multifunction frame (11) that makes it possible to mount lamps (12) (see Figure 2). This allows to take advantage of the electrical outlet for the panel to power said lamps (12) as well. The multifunction frame comprises, in this example of the invention, two sectors (11a, 11b) between which a thermal bridge breaking element (11c) is arranged. One of said sectors (11a) constitutes the frame itself of the panel (1), while the other sector (llb) implements the support and connections of a lamp (12), being able to place it on one or more of the sides of the panel ( 1), with as many lamps (12). In this way, the panel can be sized with standardized measures - usually multiples of 60 cm - of a modular ceiling (20) and replace the blind or luminaire elements that would normally be mounted in the profiles (21) of said ceiling (see figure 4). If the assembly of lamps (12) is not preferred, another sector (lld) of trim or trim can be placed, as seen in Figure 6.

The frame (11) in this example of the invention is made of aluminum, which thanks to its low emissivity coefficient cooperates in minimizing the loss of energy by infrared radiation in its field.

For its part, the controller (6) comprises a remote control interface (6a) (6aa) and a graphic display interface (6b) (6ba). These interfaces allow

35 configure all panel functionalities (1).

In this example of the invention, the controller (6) comprises a microcontroller (6d) of ARM architecture, and incorporates a controlled alternating current switch

(6e) or TRIAC interleaved in the supply to the circuit (2) and with optocoupler (6f). TRIAC trips will be made by the controller (6) at times that are empirically estimated to be the best energy use of the expected operation of the capacitor (6), predictably in the transient voltage wave regimes, so it will be calibrated to produce the connections in said transients, for which a variant of the invention has provided for the incorporation in the controller (6) of an element, not shown, for detecting the zero crossing of the mains supply voltage wave.

Finally, the invention has provided that, given its compensating function of the power factor, it can additionally incorporate a bypass (13) with a resistor (13a) in parallel with the circuit (2) and in series with the capacitor (5 ), of adequate ohmic value so that it can continue to compensate for the power factor of the general electrical installation where the panel is located

(one)

even with the infrared emission disconnected, for example in hot periods. The selection of the R-C loop consisting of the circuit (2) in series with the capacitor

(5)

or the R-C resistor loop (13a) capacitor will be governed by a selector, which may for example be implemented by a relay (23).

As possible examples of controlling the operation of the panel of the invention, the following are listed:

Continuous mode: when the circuit (2) is connected to

the alternating voltage and in the absence of the temperature sensor (7) (thermostat or thermocouple).

Mode controlled by temperature sensor (7) consisting of thermostat, capable of regulating its operation according to a certain user comfort temperature.

Temperature controlled mode (7) consisting of thermocouple f where operation is regulated by the surface temperature of the plate.

Intense switching mode Use of periodic transients. With a sufficiently large time constant, the voltage value can reach twice the permanent value, resulting in that the energy generated will be proportional to the square of the voltage. The switching is carried out at the point of the most appropriate sinusoid, with the cooperation of zero crossing detection. The switching system currently needs less than 50 ns, so with respect to the cycle of the alternate values of 50 Hz (cycle time 20 ms) the switching off time can be defined very precisely.

Notwithstanding the foregoing, and since the description given corresponds only to a preferred embodiment of the invention, it will be understood that within its essentiality multiple variations of detail may be introduced, also protected, which may affect the shape, size or the manufacturing materials of the assembly or its parts, without this implying any alteration of the invention as a whole, delimited only by the claims provided in the following.

Claims (11)

l. -Improved infrared radiant panel (1), of the type comprising a circuit (2) of resistive wire associated with a plate (3) of material with high emissivity coefficient so that a transfer of energy from the circuit (2) occurs ) towards the plate (3) I which emits it in the form of infrared radiation; characterized in that it additionally comprises: at least one refractory layer (4) of thermal inertia, at least one layer composed of a power factor compensation capacitor (5), and a power switching controller (6).

2 . -Improved infrared radiant panel (1) according to claim 1 characterized in that the refractory layer

(4)

It is arranged adjacent to the plate (3) and inside the panel,

3, -Improved infrared radiant panel (1) according to claim 2 characterized in that the capacitor (5) is arranged adjacent to the refractory layer (4), and inside the panel, 4, -Improved infrared radiant panel (1) according to any of the preceding claims characterized in that it additionally comprises a temperature sensor (7) associated with the controller (6), 5, -Improved infrared radiant panel (1) according to any of the preceding claims characterized because it additionally comprises an outer layer (8) of high emissivity of coating of the plate (3). 6, -Improved infrared radiant panel (1) according to claim 5 characterized in that the outer layer (8) incorporates protective compounds. 7. -Improved infrared radiant panel (1) according to

claim

6 characterized why the compounds

protectors

I bought nden a cap anti bacteria from painting

with

elder brother silver

8, -Improved infrared radiant panel (1) according to any of the preceding claims characterized in that it additionally comprises a thermal insulating layer (9). 9. -Improved infrared radiant panel (1) according to any of the preceding claims characterized in that it additionally comprises a reflective layer (10) envelope. 10.-Infrared radiant panel (1) improved according to any of the preceding claims characterized in that it additionally comprises a multifunction frame

(eleven)

for mounting lamps (12).

eleven . -Improved radiant panel (1) improved according to claim 10 characterized in that the multifunction frame (11) comprises two sectors (flame, 11b) between which a thermal bridge breaking element is arranged

(llc), one of said sectors (lla) constituting the panel frame (1) while the other sector (11b) implements supports and connections for a lamp (12) 12. -Improved infrared radiant panel (1) according to claim 10 characterized in that the multifunction frame (11) comprises two sectors (lla, llb) between which a thermal bridge breaking element is arranged (lle) I constituting one of said sectors (lla) the frame of the panel (1) while the other sector (lId) constitutes a beautifier. 13. -Improved infrared radiant panel (1) according to any of claims 10 to 12 characterized in that the multifunction frame (11) is made of aluminum. 14. -Improved infrared radiant panel (1) according to any of the preceding claims characterized in that the controller (6) comprises a remote control interface (6a) (6aa) and / or graphic display interface (6b) (6ba) . Infrared radiant panel (1) according to any of the preceding claims characterized in that the controller (6) comprises a controlled alternating current switch (6e). 16 - Enhanced infrared radiant panel (1) according to claim 15 characterized in that the controlled alternating current switch (6e) is calibrated to produce the transient connections of the mains supply voltage wave. 17.-Improved infrared radiant panel (1) according to claim 16 characterized in that the controller (6) incorporates a zero-pass detection element of the mains supply voltage wave. 18. -Improved infrared radiant panel (1) according to any of the preceding claims characterized in that it additionally comprises a bypass (13) with a resistor (13a) in parallel with the circuit (2) and in 5 series with the condenser (5), of ohmic value suitable for compensation of the power factor of the general installation in the disconnection of the heat generation function.