RU2262641C2 - Air distributing cap for convector - Google Patents

Abstract

FIELD: air-conditioning systems; air distributing caps.

SUBSTANCE: air distributing cap mounted in upper part of heating appliance or air-conditioning appliance at natural or forced confection is used for control of flow rate and direction of air escaping from convector. Proposed cap is designed for distribution of air escaping from heating appliance or from air-conditioning appliance at natural or forced confection. Cap is provided with reflector with one or several blades; each blade may be oriented in such way that it is inclined relative to vertical and its outer edge is directed towards wall on which appliance is secured. Heating unit has air distributing cap.

EFFECT: enhanced efficiency.

21 cl, 5 dwg

Description

The present invention relates to an air distribution cap, which should be mounted on top of a heating device or a device for air conditioning with natural or forced convection and which is designed to control both the flow rate and direction of air leaving the convector.

The heating devices commonly used for heating residential premises and offices include a heat exchanger with a finned surface and a coil for circulating hot water, connected to the heating system of the living room, and a housing with holes in the lower and upper surfaces that allow air to pass into the device and through the heat exchanger with ribbed surface.

There are two types of such heating devices: natural convection devices and forced convection devices (convectors with fans). In convectors with fans, the fan is located under the finned heat exchanger and provides extremely efficient forced air convection. On the other hand, in devices with natural convection, the air flow is created by movements observed in the mass of the fluid and caused by the instability of forces arising in the process of heat transfer. When hot water is supplied to the heat exchanger, convection is initiated due to the pressure drop that arises between the column of calm, cold air outside the convector and the column of hot air inside the convector, so that a traction occurs.

It is also known the practice of covering conventional heaters with natural circulation or radiators with suitable covers, designed both to improve their appearance and to prevent energy dissipation in directions that are not useful from the point of view of the suitability of the room for living. For this purpose, the casings or housings are equipped with front grilles that allow directing the flow of hot air in the middle of the room and thus minimizing the dispersion with the best use of the heat coming from the natural circulation heater or radiator. The disadvantage of this solution, which is especially pronounced when placing the heating device below the window, is that the stream of hot air that is directed forward cannot essentially reach the surface of the window. When fogging the window, which usually occurs at very high humidity inside the living room and / or at low outside temperature, a heating device of the type described above cannot clean the glass.

The first problem underlying the present invention is therefore to provide a switchgear that can be installed on natural circulation heaters, radiators or on heating devices or air conditioning devices with natural or forced convection and which has no disadvantages discussed above.

Another problem to be solved by the present invention is directed to the need to regulate, if desired, the thermal power developed by the heating device, depending on the specific requirements of the environment. This operation, which in the case of convectors with fans is carried out by simply turning the fan on or off, can be achieved in the case of using natural circulation heaters, radiators or devices with natural convection only by periodically switching on the natural circulation of hot water.

The third problem, which relates to the present invention, is the provision of a device characterized by significant simplicity of design and flexibility in use.

The above problems are inherent in the cap, known from US patent No. 5771708, published 30.06.1998 and which is the closest analogue of the present invention, which, however, allows you to solve the air cap, the description of which is given in the attached claims.

Other features and advantages of the air cap that is the subject of the present invention will become more apparent from the description of some preferred embodiments below with reference to the accompanying drawings, which do not limit the scope of the invention, in which:

figure 1 shows a three-dimensional image of the air cap;

figure 2 shows a side view showing the cap of figure 1 in section;

figure 3 shows a side view showing in section a heating device with natural convection, which contains a distribution cap, which is the subject of the present invention;

4 shows a side view of a reflector of a cap according to a second embodiment of the present invention; and

Fig. 5 is a side view showing a sectional detail of a heating device or an air conditioning device according to a possible use of the reflector shown in Fig. 4.

Next, with reference to the accompanying drawings will be described air distribution cap, which is the subject of the present invention. As shown in figure 1, the distribution cap, indicated generally by the position 1, consists of a frame 2, on which the reflector is supported with rotation around the axis.

The frame 2 is open from below and contains on top the rear part 4, which should be facing the wall on which the heating device is mounted, and the front part 5 with a substantially rectangular hole 6 in which the reflector 3 is placed.

Inside the hole 6 of the frame 2 there are many parallel ribs 1 located in planes perpendicular to the longitudinal axis of the distribution cap 1. The ribs 7, designed to direct the hot air leaving the convector, are fastened with known fixing means (such as, for example, bolts with the nuts shown in FIG. 2) to the inner side of the front wall 8 of the frame 2 and protrude from it in the direction of the inner part of the hole 6 to approximately its midline. On the other hand, the ribs 7 are pivotally connected to the front wall 8 so as to be able to rotate. In this case, the movement of the ribs is provided by a suitable electrical or manual control system.

The ribs 7 having a substantially irregular polygonal shape have angles 7 'formed by the inner side 16 and the upper side 17 of the ribs, which are substantially rounded.

In the case of a heating device with natural convection, the set of ribs 7 is preferably not placed inside the device, since at a low speed that the air reaches the outlet, it is difficult to orient this flow in a horizontal plane; their presence may therefore cause an excessive decrease in hot air pressure at the outlet of the convector.

The front part 5 of the frame 2 contains a control panel 9 of the heating device, operatively connected in a known and conventional manner with an electric actuator 10, which rotates the reflector 3, and in the case of a convector with a fan, with a fan, which includes forced convection of hot air. In an alternative and less expensive embodiment, the electric actuator 10 is replaced with a manual actuator (not shown in the drawings), such as, for example, a conventional flywheel to control the reflector 3. In another embodiment, the opening and closing of the reflector can be done manually again by direct exposure on it when the flywheel is not required.

As shown in FIG. 2, the front part 5 and the rear part 4 of the frame 2 are separated by the panel 11. In the rear part 4 of the frame 2, through holes 12 are provided for receiving means (in particular, screws) for attaching the device of the invention to the top convector bodies. In other embodiments, the openings 12 may be replaced by other fixing means, such as, for example, snap means on the convector body.

As shown in FIG. 2, the reflector 3 comprises a blade 13, the shape and dimensions of which substantially correspond to the shape and dimensions of the opening 6, so that it blocks this opening when the reflector is in the closed position. On the lower surface of the blade 13 there are one or more flat protrusions 14. These protrusions 14, which are located in planes perpendicular to the longitudinal axis of the reflector 3, are pivotally mounted for rotation on the inner side walls of the hole 6 and / or on one or more ribs 7. In the case of a reflector with a large ratio of length to width, it is recommended that the reflector be hinged to the rib or ribs to strengthen. Naturally, in this case, the edge 7, with which the reflector is connected, will not be orientable.

An electric actuator 10 (for example, a stepper motor) or a manual actuator of the type described above are connected in a known manner, for example by means of a transmission shaft, to one of the joint points 15, preferably to the end of the joint, so that the rotation of the reflector can be reflected from the outside.

The point 15, in which the protrusion 14 is pivotally fastened to the rib 7, is located next to the rounded corner 7 'of the rib. Thus, when the reflector 3 is rotated relative to the joint, there is no mutual engagement between the blade 13 and the ribs 7. The reflector 3 is shown in FIG. 2 in a fully open position by a dotted line. In this position, the blade 13 abuts against the inner side 16 of the rib, which serves as a stop.

Figure 3 shows an air distribution device of the present invention that is mounted on a natural convection heating device 18. This heating device or convector comprises a housing that is open or partially open from below so that cold air from the environment can enter. The housing 19 accommodates a heat exchanger 20, schematically shown in the drawing. The heat exchanger 20, completely ordinary, will include a coil connected by a recirculation scheme to the heating system of the room, the pipes of which pass through a series of perforated fins, forming together the so-called finned unit, designed for heat exchange. Appropriate valves or systems may also be provided for the application and control of the heating water flow. On the other hand, the heat exchanger 20 may be a conventional natural circulation heat exchanger or a radiator made, for example, of cast iron, steel or aluminum.

The housing 19 will also contain one or more sockets 21, intended for means of fastening the device to the wall, and / or legs 22. The legs 22 may be sized to hide any water supply pipes that can be brought to the device through the floor. However, it is obvious that the base of the casing must be raised above the floor to allow air to enter the convector.

As shown in FIG. 3, in this embodiment, the distribution cap 1 does not contain ribs 7 so as not to cause a drop in the exhaust air flow rate. Therefore, the reflector 3 will be pivotally fastened, exclusively with its two ends, with the cap itself.

In the embodiment shown in figures 4 and 5, the blade 113 of the reflector 103 has the shape of a roof with two slightly inclined slopes 113 'and 113 ". The angle formed by the two slopes is preferably about 168 °. This shape allows better directing of hot air. outgoing from the convector, which will be further described below: Two pins 123 (of which only one is shown, while the other is located respectively on the opposite side) protrude from the lateral edges of one of the two slopes 113 'and are designed to be rotatable joints in respective sockets located on the side walls of the hole 6. These pins 123 form the articulation points of the reflector 103. Preferably, the pins 123 are located approximately one third of the width of the ramp 113 ', counting from the ridge line between the two ramps. As shown in FIG. 5, the reflector 103 can also be mounted directly on the upper edges of the housing of the heating device or air conditioning device. These edges of the housing should therefore have the appropriate shape shown in the drawing, and the holes for accommodating the pins 113 should be made in their side walls.

The air cap of the present invention may be made of either metal or plastic. The latter material is particularly advantageous in terms of cost of the device.

Next will be described the operation of the air cap, which is the subject of the present invention, also with reference to the drawings.

As mentioned above, the cap 1 can be installed, for example, by means of bolts and nuts on the upper surface of the housing of the heating device with forced or natural convection, the latter can be in the form of a casing of a conventional heater with natural circulation or radiator. The cap 1, which is the subject of the present invention, will therefore be installed instead of the cover of this device. In the case of devices with natural convection, a distributor cap having no ribs 7 is preferably used. The reflector 3, 103 is rotated relative to the joint, opening it to the necessary degree by means of an electric control system acting on the electric actuator 10, or by using a manual control system. When operated manually, the reflector is held in a stop position by means of known locks or suitable counterweights. These devices are well known to those skilled in the art and therefore will not be described in detail. When using an electric actuator, the desired position will be maintained by the actuator itself (for example, a stepper motor).

The reflector can be rotated to a position in which, having passed through a vertical position, it tilts slightly, with its outer edge facing the wall on which the convector is mounted. In the cap 1 provided with ribs, the fact that the inner side 16 of the rib 7 is slightly inclined, i.e. the angle formed by this side and the upper side 17 is less than 90 °, means that the blade 13 can occupy the position described above, in which it deviates from the vertical. Due to the orientability of the blade described above, part of the air leaving the heating device is directed to the wall and, therefore, to the window located above it, as shown by the arrows in FIGS. 2 and 3. If the cap 1 has a reflector 113 with a blade in the shape of a roof , you can easily see that the exhaust air is directed to the wall by the first ramp 113 ', while the second ramp 113 "contains a fan-shaped opening, which creates a more powerful curtain of hot air around the window located above it.

Reflector 3, 103 can be installed in any position between the position when it is fully closed and the position when it is fully open, which, of course, will be the most preferable position if necessary to eliminate fogging of the glass of any window located above the heater, or, in any case when you want to get the maximum heating power of the device. However, if the room is overheated, the reflector can be completely closed so as to block the air outlet 6.

The advantages of the air cap of the present invention are apparent from the previous description.

Firstly, cap 1 forms a device that can be easily installed on convectors with forced or natural convection, for example on conventional heaters with natural circulation and radiators already installed.

In addition, its structural simplicity, which is associated, in particular, with the presence of one blade 13 in the reflector 113, is reflected in its low cost, which makes the distribution cap, which is the subject of the present invention, also suitable for use in the least expensive heating devices. A significant advantage of the cap of the present invention is that the reflector 3, 103 can be oriented so as to take an inclined position, facing the wall and any window located above it, so as to direct the flow of hot air to the misted glass and provide quick and effective anti-fogging.

By means of an air distribution cap, which is the subject of the present invention, effective dosing of the amount of air leaving the convector and, therefore, precise control of the heating power of the heating device is achieved. This is especially convenient for devices with natural convection, especially in conventional systems with natural circulation, in which the regulation of heating is usually achieved by interrupting the natural circulation of hot water with the risk of air bubbles entering the system. However, with the device of the invention, the heating of the room can be interrupted at will simply by moving the reflector to the closed position.

Of course, only a few specific embodiments of the air cap that is the subject of the present invention have been described here, however, those skilled in the art can relate to it all the modifications required to adapt them to a particular application without deviating from the protection limits of the present invention.

For example, opening and closing the reflector 3, 103 can be performed automatically by a central control device connected to a thermostat set to a predetermined temperature. An example of automatic control by a thermostat is described in the European patent application published April 22, 1998 under No. EP 0837288 in the name of the applicant of the present patent application and the description of which is incorporated herein by reference.

In addition, cap 1 can also be used in air conditioning devices or devices used both as coolers and heaters.

A heating device with an air distribution cap, which is the subject of the present invention, can also be mounted on the ceiling. In this case, the use of a reflector 103 with a blade 113 in the shape of a roof makes it possible to better direct air into the room.

Naturally, although the single-blade embodiment described above is the preferred embodiment of the present invention, the reflector 3, 103 may also include two or more vanes.

Claims (21)

1. A cap (1) for distributing air leaving a heating device or a device for air conditioning with natural or forced convection, characterized in that it contains a reflector (3, 103) having one or more blades (13, 113), and each blade is able to orient itself in such a way as to occupy a position in which it is inclined relative to the vertical so that its outer edge faces the wall on which the device is mounted. 2. The cap according to claim 1, characterized in that the reflector (3, 103) contains one blade (13, 113). 3. The cap according to claim 1 or 2, characterized in that the reflector (3, 103) can be oriented manually. 4. The cap according to claim 1 or 2, in which the reflector (3, 103) can be oriented by means of a suitably controlled electrical actuator (10). 5. A cap according to any one of claims 1 to 4, characterized in that it can be attached to the top of the housing (19) of the heating device or device for air conditioning using suitable fastening means. 6. The cap according to claim 5, characterized in that the fastening means are a system of screws with nuts or snap means. 7. A cap according to any one of claims 1 to 6, characterized in that it comprises a frame (2), on which a reflector (3, 103) rests with the possibility of rotation around the axis, and the frame (2) is open from below and contains a back part (4), which should be facing the wall on which the device is mounted, and the front part (5) having a substantially rectangular opening in which the reflector (3, 103) is placed. 8. The cap according to claim 7, characterized in that inside the hole (6) in the frame (2) there are many parallel ribs (7) lying in planes perpendicular to the longitudinal axis of the distribution cap (1). 9. The cap according to claim 8, characterized in that the ribs (7) are made with the possibility of orientation. 10. A cap according to any one of claims 1 to 9, characterized in that the reflector (3, 103) contains a blade (13, 113), the shape and dimensions of which essentially correspond to the shape and dimensions of the hole (6) so that it blocks this hole when the reflector is in the closed position. 11. The cap according to claim 10, characterized in that on the lower surface of the blade (13) are two or more flat protrusions (14) that lie in planes perpendicular to the longitudinal axis of the reflector (3), and the flat protrusions (14) are pivotally mounted for rotation on the inner side walls of the hole (6) and / or on one or more ribs (7). 12. A cap according to any one of claims 1 to 10, characterized in that the blade (113) of the reflector (103) has the shape of a roof with two slightly inclined slopes (113 ', 113 "). 13. The cap according to item 12, characterized in that the angle formed by the slopes (113 ', 113 ") is approximately equal to 168 °. 14. Cap according to claim 12 or 13, characterized in that two pins (123) protrude from the lateral edges of one of the two slopes (113 '), which are designed to be rotatably mounted in respective sockets located on the side walls of the hole (6 ) 15. The cap according to claim 14, wherein the pins (123) are located at a distance equal to approximately one third of the ramp width (113 '), counting from the ridge line between the two ramps. 16. A cap according to any one of claims 12 to 15, characterized in that the blade (113) is mounted directly on the upper edges of the housing of the heating device or the air conditioning device, the pins (123) being inserted into the corresponding holes made in the side walls of the housing. 17. The cap according to any one of claims 1 to 16, characterized in that the air distribution cap (1) is made of plastic. 18. Heating device or device for air conditioning with forced convection or natural convection, characterized in that it contains a cap for distributing air according to any one of claims 1 to 17. 19. The heating device or device for air conditioning according p, characterized in that it is made with the possibility of installation on the wall. 20. A heating device or device for air conditioning according to claim 18 or claim 19, characterized in that the opening and closing of the reflector (3, 103) is performed automatically by a central control unit connected to a thermostat. 21. The heating device or device for air conditioning according to any one of paragraphs.18-20, characterized in that it is made with the possibility of mounting to the ceiling.

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