| WO2007067082A1 | 2007-06-14 |
| US2069190A | 1937-01-26 | |||
| US2151725A | 1939-03-28 | |||
| US2069732A | 1937-02-02 |
| PATENT CLAIMS
1. A mounting and installation system of specially adapted components that can be combined in different ways to "tailor-make" an air transporter unit that has the purpose of increasing the air's transport of the heat or cold that the air takes from a unit, often named a radiator, this latter being the unit that delivers heating or cooling to its surrounding, adjoining space, the whole being characterised by: the mounting and installation system being flexibly structured so that the number of fan units and the thereto appertaining chassis components can be widely varied and that these fan units can be mounted to any desired width and depth, the whole, when mounted, guiding air towards said radiator via the use of chassis components that are installed on or next to the radiator using mounting components, it being possible to vary the amount and speed of the air via different speeds of the fan motor(s), the design of the chassis components ensuring that the air is transported near said radiator or the corresponding heated or cooled body, this resulting in an increase of the radiator's/body's normal capacity.
2. A mounting and installation system of specially adapted components as per one or more of the patent claim 1 above, characterised by: it being possible to mount the unit in conjunction with (either under, over, behind or in front of) commonly used radiators with the purpose of, via increased air flow, increasing the extraction of emitted temperature from said radiator.
3. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: it being possible for the fan unit to comprise at least one fan, but it also being possible to connect together, as necessary, several fans and vary the format in two dimensions (most particularly width and depth) using the components of the mounting and installation system.
4. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: it being possible for the fan unit to comprise at least one fan, but it also being possible, using a component (701) that is unique to the system, to connect several fans together.
5. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: the fan (101) in the mounting and installation system being suspended using a vibration- damping material (301).
6. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: the system's fan (101) being mounted using a component (301) in a vibration-damping material that simplifies and reduces the cost of production operations because, at mounting, said material can be stretched, thereby reducing in dimension and allowing it to be threaded through a hole, or corresponding opening(s), so that, when stretching ceases, said damper returns to the intended size and, when this happens in a mounting opening, connects the fan with a chassis component, the fan thus being mounted to a chassis component via the damper.
7. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: it being possible for the mounting and installation system to contain an apparatus in the nature of an electronic or mechanical temperature sensor that, as a function of temperature, automatically controls the speed of said fan(s).
8. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: it being possible for the system to contain apparatus in the nature of moisture sensors that control the starting and the speed of the fan motor(s).
9. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: it being possible for the system to contain temperature and/or moisture sensors that can give an alarm when there is a risk of condensation.
10. A mounting and installation system of specially adapted components as per one or more of the patent claims above, characterised by: there being an air dehumidifying unit, preferably wholly or partly integrated in a module. |
FLEXIBLE MOUNTING AND INSTALLATION SYSTEM WITH COMPONENTS SPECIALLY ADAPTED FOR THE TRANSPORT OF AIR
TECHNICAL BACKGROUND
In order to increase the extraction of energy from a heated or cooled unit often referred to as a radiator, there is sometimes a need to increase the transport of air around said unit. If the radiator is hotter than the surrounding air, heat transfer can be increased by increasing the speed of the air flow past the radiator's surface. In the same way, the exchange from a cold surface can be increased by increasing the speed of the air flow past the cooled unit.
A common problem today is that traditional buildings with waterborne heating systems are often dimensioned for high boiler temperatures. Thus, the temperature of the outgoing water that is to be transported around the radiators is relatively high. Such temperatures are normally generated using electric boilers or boilers fired by wood, pellets or oil. If such a system is altered and the heat source changed to an air or geothermal energy system, it is not economical to produce high-temperature heat. At temperatures that are too high, the heat pump shuts down and electrical heaters produce the heat. Heat pump manufacturers recommend low-temperature radiators. Using the present device, low-temperature radiators are a common element in the system. There can be unpleasant consequences if, because of a lower boiler temperature, the radiators designed for the heat requirements of the premises cannot give off sufficient heat. A solution to said problem is to increase the air flow around the radiator and thereby extract more energy from the radiator.
If more heat is required, a radiator is normally replaced with one that has a larger surface. Rather than increasing a radiator's surface by investing in a larger unit (and installation thereof), great savings are made, from a financial point of view, by choosing, instead of said unit, the air transporter described herein. Furthermore, a larger radiator takes up more space and is perceived as less aesthetically pleasing than a smaller one.
As the output temperature from a heat pump can be held lower by using said air transporter unit to increase the efficiency of the radiators, the efficiency of the heat pump increases by up
to 40% with a correspondingly much lower energy consumption. At the same time, compressor pressure falls. This must be good for its service life.
There is often a wish that the rebuilding of a kitchen should provide more work surfaces. As a result, worktops are sometimes built over radiators. This considerably impedes ventilation and heat transfer. In such cases, the air transporter described in this document supplies a solution. The same applies where furniture, curtains, window sills, radiator covers or anything else reduce heat emissions from a radiator - the device in this document can compensate for the reduction.
Experience shows that radiators in basements are often too small and, consequently, that it is difficult to achieve good heat distribution. Findings from tests using the described air transporter have been very good. After installation of said air transport system, basement areas are perceived to have better, drier and healthier air. There is less "stagnant" air with its associated unpleasant odour. The air flow can be suitably controlled using a system, as described in this document, comprising a modularly built air transporter unit.
Now, when energy prices are so high and we so clearly see the need to save energy, the technology here described offers many new possibilities to lower the temperature in, for example, public buildings such as churches, large meeting places and other premises that are used on certain days only. There is then also a concomitant need to rapidly raise the heat. In churches, which have high ceilings, this air transporter unit can considerably shorten the heating time. Of course, this is the case for all rooms and buildings where it is desired to rapidly raise the heat provided by radiators in waterborne systems. Without the fans, heat rises to the roof, descends slowly and finally heats the floor. Using this device, the cold air at the floor is sucked in by the fans and is heated far more rapidly by the radiator.
The technology of using a fan to increase air flow at a radiator is already known. See, for example, American patent 2069732 (granted in 1937). This is very different from the module system that, described in the present document, uses independent components (in a system) to "tailor" a solution for widely varying sizes and designs of radiators.
Where spaces are to be cooled (that is, in contrast to the above, the temperature is to be lowered), this can be done by cooling the radiators via the medium flowing through these, the
purpose being to lower the ambient temperature. To prevent moisture condensing on the radiator, some sort of dehumidifying device is required. A device that shuts off the cooling when there is condensation can be added to the unit. A larger variant could include an air dehumidifier integrated, more or less, in the unit.
A fundamental idea in the described system of units is, simply put, "IKEA model". In other words, the customer buys the components he/she needs and carries out mounting and installation himself/herself. To the benefit of the consumer, this lowers costs at all stages. From today's modern, slimline models to the older, heavier models still used in older buildings, the sizes and designs of various radiators are well known.
The system described in this document gives flexibility in two dimensions, i.e. width and depth. As the modules can be combined in different ways (see figures), this also means that it is easy to avoid having the fan exactly opposite an obstruction, e.g. a radiator feed pipe in the middle of the radiator. The width module should preferably be 5 cm with any length extension. The depth can be varied linearly to accommodate from one fan to any number of fans. Using a special connecting unit of fans, the depth does not need to be altered in steps of one fan unit (see explanatory figures).
There is no known fan unit on the market that takes into account all these designs. For this reason, the fan answers a real consumer need.
BRIEF ACCOUNT OF THE INVENTION
A FIRST DESIGN POSSIBILITY
In a first design possibility (see figure 1), the unit comprises a fan and electric motor (101) suspended using rubber straps (301). The rubber straps make mounting easy and also reduce the propagation and transportation (through/to other system components) of any fan vibrations. The rigid mounting of a vibrating unit to a rigid body such as a profile generates structure-borne sound. The fans (101) are of a design that is often used for the normal cooling of computer equipment and similar. The chosen fan manufacturer employs a unique property that, as a function of the amount of power supplied, allows the speed to be adjusted within a wide range (using an electric fan with easily adjustable speed).
In this design, the components for guiding the air are chassis components (202 and 203) in plastic. They are manufactured in a specially designed mould. The chassis has special cut-outs that, via a snap-fit arrangement, enable the connection of further chassis. Mounting is therefore very simple and there is great flexibility. The chassis component (203) to which the fan (101) is mounted has an intermediate piece (202) without a fan and side pieces (201 and 204) - see figure 2, which shows all plastic components. These are all manufactured in the same way and, for easy mounting, also have said snap-fit function. For increased flexibility, the components can be combined in various ways. The number of fans can be increased or decreased and obstacles can be bypassed without this being visible from the front. The fan (fans) is (are) mounted in the chassis using said rubber straps (301) in a simple fashion. Strap diameter decreases when the strap is elongated and, in this way, the strap can be mounted in the holes in the chassis and the corresponding mounting holes in said fan's frame.
SHORT DESCRIPTION OF THE FIGURES The present invention is described in some detail with the assistance of the following figures:
Figure 1 shows a mounted unit installed on a radiator.
Figure 2 shows various chassis components in the module system.
Figure 3 shows a component for mounting fan to chassis.
Figure 4 shows mounting components. Figure 5 shows mounting components.
Figure 6 shows a mounted fan unit.
Figure 7 shows a special component.
DETAILED DESCRIPTION OF A PREFERRED DESIGN OF THE INVENTION
Figure 1 shows a design in which a fan element is made up of a number of fans (101). There are mounting components (see figures 4 and 5) for holding the arrangement in place and a chassis that is made up of a number of plastic modules (see figure 2). The unit is mounted to a radiator (601).
The module system for chassis components as in figure 2 is, in the preferred design, made in plastic, an injection method being used to form the design's components in a mould. Retaining the same function of allowing fans to be mounted to the chassis (the chassis also guiding air flows as desired), the chassis components can also be made in sheet metal or any
other suitable material. In this design, there are 5 individual plastic components in the chassis. However, the invention is not tied to this design or number of components.
Figure 2 shows how a small module can be built up from the chassis components: left side piece (201), intermediate piece (202), fan mounting component (203) and right side piece (204). The design of the plastic components includes a simple snap-fit function comprising holes (210) that, along with specially designed tabs (211), allow the components to be easily "snapped together". The tabs (211) are pushed into said holes (210), the fit being designed to make the unit stable. The described mounting method is particularly suitable for "DIYers" who, with a simple description, can carry out mounting quickly and reliably with no further mounting components or extras such as glue, etc.
Figure 3 shows a mounting element (301), preferably in a material with rubberlike properties, that allows the fan (101) to be easily mounted to the chassis without using screws or other common fastening components. The mounting element is elongated by stretching it lengthways after one end has been inserted in the appropriate mounting hole in the fan's chassis. Elongation decreases the diameter and the element can be pulled into the fan's hole. When stretching is released, the mounting element, thanks to its profiles, sits securely in the hole. In the same way, the fan is then mounted in the corresponding mounting hole in the chassis (203). An easier mounting method is hard to imagine and there is the additional advantage that vibrations from the fan's rotation are not transmitted and/or amplified in/by the chassis components.
Figures 4 and 5 show components for mounting the fan unit to various types of radiators. The final number of variants has not been decided, but the figures show example designs.
Figure 6 shows (viewed from above) a fan unit mounted to a radiator (601).
Figure 7 shows how a special component (701) can be used to vary the number of fans in, and also the depth of, a fan system using the special mounting components shown in figure 1. The mounting component in figure 7 makes it possible to mount fans (101) between the separation distance given by each fan's cut-outs for fastening with a rubber component as per figure 3.