1. Field of Invention
The present invention relates generally to hydronic heating systems in general and in particular to an apparatus for providing a modular localized hydronic heating supply.
2. Description of Related Art
Hydronic heating is a common heating system primarily used for heating floors, although walls and ceilings may also be heated. It is known that the systems used within the field of hydronic, may be complicated and expensive and are commonly required to be installed by qualified and skilled professionals.
Installation of hydronic heating systems within buildings, whether during initial construction or afterwards as a retrofit during renovations and remodeling has been historically very time consuming as well as entailing a lot of skilled labour. In particular, the boiler, controls and distribution systems are generally installed in one location such as in a basement or dedicated mechanical room. A network of fluid distribution pipes must then be routed throughout the buildings floors, walls and ceilings to the locations where the heat is desired.
Difficulties with such routing of piping and the like includes the possibility that the routing of the pipes or fluid conduits through the building walls, floors and ceilings to their destination point may put the piping in a place of potential damage. Additionally thermostats need to be routed from each of the rooms being serviced back to the system controls. For example, a nail or screw may be forced through the structural material and puncture the pipe. This creates potential for such damage to be caused in locations that cannot be accessed or seen. This may lead to great cost to the owner and or potentially the contractors involved.
Additionally, central hydronic heating systems also suffer from inefficiencies due to the distributed design of such system. In particular, heat is lost from the piping while the heating fluid is being transported to and from the location requiring the heat. This heat loss may be in locations where heat is not required and therefore heat energy is wasted. The energy required by the pump to circulate the fluid through the network of distribution tubing can also result in waste of energy.
Distributed systems also require a large amount of space at some location within the building for the heater, storage tank and associated hardware. It will be appreciated that the need to keep large volumes of water heated and kept at a relatively high temperature even when no heat is required to respond to any future demands contributing an additional waste of energy. Inevitably some of this heat will dissipate through a system's insulation (if there is any) and generally overheat the space in which the function is taking place. In addition, when fossil fuel type heating systems are used the heat given off from flue gasses into the flue pipe system is wasted heat. All of these losses can be classified as parasitic losses in the standard system designs which reduces the efficiency and thereby the effectiveness of such systems.
Additionally, attempts to renovate an existing building to include in-floor heating via hydronics have created additional difficulties. Within an existing finished building, such renovations typically requires cutting into walls floors and ceilings of building to rout the distribution pipe work. All of which requires repair and renewal after the piping has been installed.
According to a first embodiment of the present invention there is disclosed an apparatus for heating a hydronic heating fluid comprising a casing body having an inlet and an outlet adjacent to the inlet and a fluid flow path between the inlet and outlets. The flow path extends along first and second substantially straight sections with a return bend therebetween. The apparatus further includes a heating element located within one of the first or second sections of the flow path.
The first and second straight sections may be substantially parallel to each other. The first and second straight sections may extend substantially horizontal. The casing may extend between first and second ends wherein the inlet and outlet are located at the first end and the return bend is located at the second end.
The second end may include a heater bore aligned with the second section wherein the heating element is securable within the second section through the heater bore. The second section may include a heat sensor. The heating element may be turned off in response to the heat sensor sensing a predetermined set temperature. The return bend may further include a fluid expansion chamber.
The first end may include a pump in fluidic communication with the inlet, the pump being operable to draw the heating fluid in through the inlet and to discharge the heating fluid through the first section of the casing body. The pump may comprise a centrifugal pump. The pump may have a central axis extending substantially parallel to the first and second sections of the casing body.
The inlet and outlet may extend substantially downwardly from the casing body proximate to the first end thereof. The inlet and outlet may be formed through a common leg extending from the casing body.
The apparatus may further comprise a distribution manifold having a riser engageable upon the downspout. The riser may include a supply conduit in fluidic communication with the outlet of the casing body and a return conduit in in fluidic communication with the inlet of the casing body. The supply and return conduits may be formed within a common tubular member.
The distribution manifold may include a supply connection in fluidic communication with the supply conduit operable to be connected to a supply line of a hydronic heating tube and a return connection in fluidic communication with return conduit operable to be connected to a return line of a hydronic heating tube
The first section may include a fill and release valve with a diverter valve therebetween. The first section may include at least one gauge operable to display a condition within the system.
The casing body may be formed of connectable first and second casing halves. The first and second casing halves may be secured to each other with fasteners.
Other aspects and features of the present invention will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments of the invention in conjunction with the accompanying figures.
In drawings which illustrate embodiments of the invention wherein similar characters of reference denote corresponding parts in each view,
Referring to
With reference to
The casing body 22 comprises a unitary body extending between first and second ends, 24 and 26, respectively. The inlet port 28 and outlet port 29 extend through a bottom of the casing body 22 proximate to the first end 24 and are adapted to introduce and remove the heating fluid from the casing body 22 as will be more fully described below.
The casing body 22 defines a flow path 30 extending along a top or first flow section 32 and returning along a bottom or second flow section 34 with a return bend 36 located therebetween. As illustrated, the casing body 22 may be formed of a pair of substantially parallel top and bottom tubular bodies, 38 and 40, respectively each containing and defining the first or second flow sections 32 and 34. Optionally, the casing body may comprise a unitary body of any desired shape.
As illustrated in
Additionally, the size and type of each port 42 will be selected to correspond to the size and type of each component which is intended to be located at such location. It will be appreciated that each of the above system components may also be located at different places along the casing body as desired by a user.
The top tubular body 38 may also include a diverter valve 52 located between the make-up and release valves 46 and 44 which is operable to divert the flow of fluid out of the apparatus 20 through the release valve 46 for collection by an external system (not shown) and to introduce a fluid flow in through the make-up valve 44 from such external system. Such diversion may be useful for exchanging or adding heating fluid to the apparatus as needed from time to time. The apparatus 20 may also include a fluid expansion chamber 54 adapted to receive an extra quantity of the heating fluid above the capacity of the heating system utilizing the apparatus 20. Examples of such expansion chamber, valves, pressure release valve and air bleed valve are well known in the art. As illustrated, the fluid expansion chamber 54 may include an expandable bladder 86 adapted to receive such extra fluid.
As illustrated in
The second end 26 of the casing body 22 includes a heater bore 70 extending therethrough with a heater mounting flange 72 located therearound. A heater 74 is provided with a mounting plate 76 adapted to sealably engage the heater and heater mounting plate on the heater mounting flange, such as, by way of bolting, threading, adhesives, gaskets or the like. The heater 74 may be of any suitable type, such as, by way of non-limiting example, an electric heating element as illustrated. The heater 74 will be selected to have a capacity corresponding to the heating needs of the room to be heated and may be of an electric resistance type as are commonly known.
With reference to
As illustrated in
The casing body 22 may be formed of any suitable material, such as, by way of non-limiting example, plastic, composite materials or metal, including steel, copper, stainless steel, aluminium, or iron. The casing body 22 may be formed by any conventionally known process including machining, welding, soldering adhering or braising separate components together. The casing body 22 may also be formed by casting, moulding or any other suitable process. In particular, the casing body 22 may be formed of first and second casing halves 90 and 92 which may be bolted adhered or otherwise connected to each other to form the completed casing body 22.
With reference to
Turning now to
Turning now to
The apparatus 20 may also include a manifold 130 for distributing the heating fluid to and from the casing body 22. The manifold comprises a riser 131 and includes an inlet side 132 and an outlet side 134 separated by a center wall 106 and one or more water distribution tubes 136 extending therefrom. The inlet and outlet sides 132 and 134 are separated from each other so as to sealably connect with the inlet and outlet ports 28 and 29 of the casing body wherein the center wall will align with the dividing plate 102. Each of the manifold 130 and common tubular member 108 may include a flange, 109 and 138, respectively for clamping together according to any known means, such as bolts, adhesives, welding, braising or clamp rings 140. It will be appreciated that providing the casing body separate from the manifold permits simple heater and component exchange and maintenance without cutting into plumbing tubes. This will be especially useful when the system is mounted within a wall. As illustrated in
As described above, the apparatus 20 provides a localized heat source for hydronic heating systems. The system, provides a compact footprint by running the required flow through the system in parallel to itself thereby minimizing the overall length required. In particular, for many applications, the apparatus may have a length of less than 24 inches thereby permitting the apparatus 20 to be located between wall studs with no modification thereto. Accordingly, the apparatus may be further recessed into the wall interior reducing any special impacts on the room. The apparatus 20 may also be located and mounted within a room by any other conventionally known means, such as wall mounted brackets, covering with a base board or the like. By providing the heating source at the location where the heat is to be required, it will also be appreciated, that any excess heat which is transmitted through the casing body or associated components of the system is not wasted, as such heat will be utilized by the room to achieve the desired temperature, thus increasing efficiency over conventional designs.
While specific embodiments of the invention have been described and illustrated, such embodiments should be considered illustrative of the invention only and not as limiting the invention as construed in accordance with the accompanying claims.