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Title:
SPACE HEATING SYSTEM FOR VEHICLES AND PORTABLE STRUCTURES
Document Type and Number:
WIPO Patent Application WO/2016/037989
Kind Code:
A1
Abstract:
A space heating system 12 comprising a space heater 24 and at least one radiator duct 38 connected to an air outlet of the space heater. The duct 38 is formed from thermally conductive material such that it acts, in use, as a heat radiator. Each radiator duct may be connected between an air inlet 28,29 and air outlet 30,31 of the space heater to form a radiator loop. Alternatively, each radiator duct may extend from an air outlet 30,31 of the space heater terminating at a free end 66 and having a plurality of outlets 70 formed in its body, especially near the free end.

Inventors:
MCFARLAND STANLEY (GB)
Application Number:
PCT/EP2015/070409
Publication Date:
March 17, 2016
Filing Date:
September 07, 2015
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
MUNSTER SIMMS ENG LTD (GB)
International Classes:
B60H1/00; B60P3/32; F24D5/06; F24F13/02
Foreign References:
DE1755132A11971-09-09
DE6910683U1969-09-04
US2587871A1952-03-04
US2240951A1941-05-06
DE202005017225U12007-03-15
GB1589196A1981-05-07
Attorney, Agent or Firm:
WALLACE, Alan (4 Mount Charles, Belfast Antrim BT7 1NZ, GB)
Download PDF:
Claims:
CLAIMS:

1. A space heating system comprising: a space heater having at least one air inlet and at least one air outlet; and at least one radiator duct connected to at least one of said at least one air outlet, wherein at least part of said at least one duct is formed from thermally conductive material such that it acts, in use, as a heat radiator.

2. The system of claim 1 , wherein at least one radiator duct has a first open end connected to a respective one of said at least one air outlets, and a second open end connected to a respective one of said at least one air inlets to form a radiator loop.

3. The system of claim 2, wherein said radiator loop comprises a forward portion of the respective radiator duct extending from the respective outlet to a return point, and a return portion of the respective radiator duct extending from the return point to the respective inlet, wherein said forward and return portions run side-by-side, preferably substantially parallel with one another.

4. The system of any preceding claim, wherein at least one radiator duct has a first open end connected to respective one of said at least one outlets, and extends from said respective outlet, terminating at a free end. 5. The system of claim 4, wherein said free end is closed, or closable by means of a closable vent.

6. The system of claim 4 or 5, wherein at least one, preferably a plurality of, outlets are formed in said at least one radiator duct between said open end and said free end. 7. The system of claim 6, wherein there is a plurality of said outlets mutually spaced apart in the longitudinal direction of the respective radiator duct.

8. The system of claim 6 or 7, wherein said at least one outlet is normally open. 9. The system of any one of claims 6 to 8, wherein one or more of said at least one outlets comprises a closable vent.

10. The system of any one of claims 6 to 9, wherein said at least one outlet is located in a distal portion of the respective radiator duct, the distal portion being separated from the respective space heater outlet by a proximal portion of the respective radiator duct.

1 1. The system of claim 10, wherein there are no outlets, or at least no normally open outlets, in said proximal portion.

12. The system of claim 10, wherein said proximal portion includes at least one outlet, but fewer than are provided in said distal portion.

13. The system of any one of claims 10 to 12, wherein said distal portion provides up to

approximately 50%, preferably up to approximately 40% or up to approximately 25%, of the total length of the respective duct.

14. The system of any one of claims 10 to 13, wherein the configuration of said at least one outlet is selected such that the distal portion provides, in use, substantially the same amount of heat to the surrounding environment as the proximal portion. 15. The system of any preceding claim, wherein said at least one radiator duct is wholly or partly metallic, for example formed wholly or partly from metal.

16. The system of any preceding claim, wherein said at least one radiator duct is flexible and/or semi-rigid.

17. The system of any preceding claim, wherein said at least one radiator duct is shaped and dimensioned to fit around the periphery of an accommodation space to be heated.

18. The system of any preceding claim, wherein one or more closable vents are provided in one or more of said radiator ducts, particularly one or more duct that is configured to form a radiator loop.

19. An accommodation structure in which the space heating system of any one of claims 1 to 18 is installed, wherein said accommodation structure includes an internal accommodation space, said at least one radiator duct being shaped and dimensioned to fit around the periphery of said

accommodation space.

20. The structure of claim 19, comprising a floor, wherein said at least one radiator duct is located above the floor, preferably substantially at floor level. 21. The structure of claim 19 or 20, wherein all or part of said at least one radiator duct is located behind and/or beneath one or more fixtures or fittings provided in the structure.

22. The structure of claim 21 , wherein one or more apertures are provided in or around said fixtures or fittings to allow air to circulate around said fixtures or fittings by convection caused, in use, by heat radiating from said at least one radiator duct.

23. The structure of any one of claims 19 to 22, wherein said accommodation space comprises a plurality of accommodation zones, wherein a respective one or more of said radiator ducts extends around the periphery of each zone. 24. The structure of claim 23, wherein each zone comprises one or more accommodation areas, for example any one or more of a living area, dining area, kitchen, washroom, toilet, shower room and/or bedroom.

25. The structure of any one of claims 19 to 24, wherein said accommodation structure is part of a vehicle or mobile or temporary structure.

Description:
Space Heating System for Vehicles and Portable Structures

Field of the Invention This invention relates to spacing heating systems especially for use with vehicles and portable structures.

Background to the Invention Space heating systems are commonly provided in vehicles such as recreational vehicles (RVs), caravans and boats, and portable structures such as mobile homes, portable cabins. Conventionally, either one of two types of system is used: a wet heating system or a blown air system.

In a typical wet heating system the heating medium is a liquid, usually water, which is pumped around a circuit comprising the radiators and pipes. Advantages of the wet system include that it is quiet and clean, and that it provides even heating of the space as well as heating the fabric of the structure in which it is installed. Disadvantages include that it is costly, heavy and does not provide instant heat. In a blown air system, air is heated and blown through thermally insulated ducting. The end of the ducting is open and serves as a vent through which heated air is expelled to heat the surrounding space. Advantages of the blown air system include that it is inexpensive, light, space saving and provides almost instant heat. Disadvantages include that it is noisy, disturbs dust, heats unevenly and tends not to heat the fabric of the structure in which it is installed.

It would be desirable to provide an improved space heating system. Summary of the Invention A first aspect of the invention provides a space heating system comprising: a space heater having at least one air inlet and at least one air outlet; and at least one radiator duct connected to at least one of said at least one air outlet, wherein at least part of said at least one duct is formed from thermally conductive material such that it acts, in use, as a heat radiator. Optionally at least one radiator duct has a first open end connected to a respective one of said at least one air outlets, and a second open end connected to a respective one of said at least one air inlets to form a radiator loop. Said radiator loop may comprise a forward portion of the respective radiator duct extending from the respective outlet to a return point, and a return portion of the respective radiator duct extending from the return point to the respective inlet, wherein said forward and return portions run side-by-side, preferably substantially parallel with one another. Optionally, at least one radiator duct has a first open end connected to respective one of said at least one outlets, and extends from said respective outlet, terminating at a free end. Said free end is preferably closed, or closable by means of a closable vent. In preferred embodiments at least one, preferably a plurality of, outlets are formed in said at least one radiator duct between said open end and said free end. The outlets may be mutually spaced apart in the longitudinal direction of the respective radiator duct. Typically said at least one outlet is normally open, and may comprise a closable vent.

Typically said at least one outlet is located in a distal portion of the respective radiator duct, the distal portion being separated from the respective space heater outlet by a proximal portion of the respective radiator duct. Also typically, there are no outlets, or at least no normally open outlets, in said proximal portion. Alternatively said proximal portion includes at least one outlet, but fewer than are provided in said distal portion. By way of example said distal portion may provide up to approximately 50%, preferably up to approximately 40% or up to approximately 25%, of the total length of the respective duct.

The preferred configuration of said at least one outlet is selected such that the distal portion provides, in use, substantially the same amount of heat to the surrounding environment as the proximal portion.

Typically, said at least one radiator duct is wholly or partly metallic, for example formed wholly or partly from metal. Preferably, said at least one radiator duct is flexible and/or semi-rigid.

In typical embodiments, said at least one radiator duct is shaped and dimensioned to fit around the periphery of an accommodation space to be heated.

Optionally, one or more closable vents are provided in one or more of said radiator ducts, particularly one or more duct that is configured to form a radiator loop. A second aspect of the invention provides an accommodation structure in which the space heating system of the first aspect of the invention is installed, wherein said accommodation structure includes an internal accommodation space, said at least one radiator duct being shaped and dimensioned to fit around the periphery of said accommodation space. Typically the structure comprises a floor, wherein said at least one radiator duct is located above the floor, preferably substantially at floor level.

In typical embodiments, all or part of said at least one radiator duct is located behind and/or beneath one or more fixtures or fittings provided in the structure. Preferably one or more apertures are provided in or around said fixtures or fittings to allow air to circulate around said fixtures or fittings by convection caused, in use, by heat radiating from said at least one radiator duct. Said accommodation space typically comprises a plurality of accommodation zones, wherein a respective one or more of said radiator ducts extends around the periphery of each zone. Each zone may comprise one or more accommodation areas, for example any one or more of a living area, dining area, kitchen, washroom, toilet, shower room and/or bedroom. In typical embodiments, said accommodation structure is part of a vehicle or mobile or temporary structure.

Further advantageous features of the invention will be apparent to those skilled in the art upon review of the following description of a specific embodiment and with reference to the accompanying drawings. Brief Description of the Drawings

An embodiment of the invention is now described by way of example and with reference to the accompanying drawings in which: Figure 1 is a plan view of a caravan in which a space heating system embodying one aspect of the invention is installed; and

Figure 2 is a schematic diagram of a space heater suitable for use with the space heating system of Figure 1.

Detailed Description of the Drawings

Referring now to Figure 1 of the drawings there is shown, generally indicated as 10, a plan view of a caravan in which there is installed a space heating system 12 embodying one aspect of the invention. It is noted that the invention is not limited to use with caravans and may be used with any structure that is shaped and dimensioned to define an internal accommodation space that requires heating. Embodiments of the invention are however particularly suited for use with vehicles, such as RVs (also known as camper vans or camping cars), caravans and boats, or with temporary or portable accommodation structures such as mobile homes or portable cabins.

The caravan 10 has an accommodation structure 1 1 , or cabin, that defines an internal

accommodation space that may be said to comprise accommodation zones. In the illustrated example, Zone 1 comprises a living area 14 and Zone 2 comprises a kitchen 16, bedrooms 18 and a washroom 20. More generally, the accommodation space may comprise one or more zones, each zone comprising one or more accommodation areas, e.g. any one or more of a living area, dining area, kitchen, washroom, toilet, shower room and/or bedroom. A space heating system 22 embodying the invention is installed in the caravan 10. The space heating system 22 comprises a space heater 24 of a type that heats a gaseous heating medium, usually air. Such heaters are commonly known as blown air space heaters. Figure 2 shows an exemplary space heater 24 comprising a body 26 having inlets 28, 29 and outlets 30, 31. Internally, the body 26 is configured, in this case by an internal divider 32, to provide a fluid flow path from the inlets 28, 29 to the outlets 30, 31 . At least one heating device 34 is provided inside the body between the inlets 28, 29 and outlets 30, 31 for heating the air as it travels along the fluid flow path. In this example, the heater 24 includes two heating devices 34, which may be of different types, e.g. an electric heater and a gas powered heater. The heater 24 includes a fan 36 that acts to draw air into the body 26 through the inlets 28, 29 and expel heated air from the outlets 30, 31 . The fan 36 may be located inside the body 26, for example in the fluid flow path as shown, and may comprise an impellor type fan. The space heater 24 typically includes a controller (not shown) which

automatically controls the operation of the heating device(s) 34 and/or the fan 36, as required, in response to the temperature measured at the inlets 28, 29 and/or outlets 30 31 by one or more temperature sensors (not shown). It will be understood that the space heater 24 may take alternative configurations to that illustrated. For example the number of inlet(s) and/or outlet(s), and/or the number and/or type of heating device may be selected to suit the application. The system 22 further comprises one or more heat radiating ducts 38 connected to one or more of the inlets 28, 29 and outlets 30, 31 of the space heater 24. At least part of, and optionally all of, each duct 38 is formed from a thermally conductive material, i.e. a material with a relatively high thermal conductivity (as distinct from a thermally insulating material, which has a relatively low thermal conductivity). For example, each duct 38 may be wholly or partly formed from a metallic or metalized material, e.g. formed from aluminium or other metal. Flexible and/or semi-rigid ducting is preferred, e.g. foil ducting. As a result, each duct 38 acts as a thermal radiator during use, i.e. transferring heat from the air inside the duct 38 to the space surrounding the exterior of the duct 38. Conveniently, each duct 38 is formed from the same material along its whole length. Alternatively, however, one or more longitudinal sections of one or more of the ducts 38 may be formed from a different material, for example a thermally insulating material, and/or may be lagged with a thermally insulating material.

The space heater 24, or at least its body 26, may be installed above or below the floor 13 of the accommodation structure 1 1 as is convenient. In cases where the body 26 is located beneath the floor 13, each duct 38 may pass through an aperture (not illustrated) provided in the floor (or elsewhere in the structure 1 1 ) for this purpose. Optionally a respective sleeve-like connector (not shown) may be connected to one or more of the inlets 28, 29 and outlets 30, 31 , in which case the connector may extend through the aperture. An inlet duct 40 is connected to one of the inlets 28 for drawing air into the system 22 from its external environment. The inlet duct 40 has an open end 42 through which air may be drawn from the environment into the heater 24 via the duct 40 and inlet 28. The open end 42 may be located inside the structure 1 1 (as illustrated), or outside of the structure 1 1 , above the floor 13 or below the floor 13, as is convenient, the duct 40 passing through the floor 13 or not, as required. In preferred embodiments, the radiating ducts 38 are located around the periphery of the structure 1 1. The ducts 38 are conveniently located above the floor 13, preferably substantially at floor level. Alternatively, the ducts 38 may be located beneath the floor 13 (or at least beneath floor level), with apertures provided in the floor 13 (or elsewhere in the structure 1 1 ) to allow radiated heat into the accommodation space.

Typically, all or part of the or each duct 38 is located behind and/or beneath one or more of the fixtures or fittings in the structure 1 1 , for example a sofa 44, table 46, work surface 48, appliance 49, cupboard 50, bed 52 or shower cubicle 54. One or more apertures (not shown) may be provided to allow air heated by each duct 38 reach the accommodation space and not to be trapped by the relevant fixture or fitting. For example, one or more apertures, e.g. gaps, may be provided in the relevant fixture(s) or fitting(s) at floor level, and/or one or more apertures, e.g. gaps, may be provided in the relevant fixture(s) or fitting(s) at the relevant internal wall(s) of the structure 1 1. This allows air to circulate around the relevant fixture(s) or fitting(s) by convection caused by the heat radiating from the duct 38. In any event, each duct 38 (or at least as much of it as possible or desired) is exposed to the accommodation space along its length to facilitate its use as a radiator.

Optionally, the or each duct 38 may be configured to form a radiator loop between one of the space heater outlets and inlets. In Figure 1 , duct 38A forms a radiator loop between outlet 30 and inlet 29. The duct 38A has first and second open ends 56, 60 connected respectively to the outlet 30 and inlet 29, which are typically located adjacent one another. The loop includes a return point 62, a forward portion of the duct 38A extending from the outlet 30 to the return point 62, and a return portion of the duct 38 extending from the return point 62 to the inlet 29. Advantageously, the forward and return portions of the duct 38A run side-by-side, preferably substantially parallel with one another. As a result, both the forward and return portions of the duct 38A may conform substantially to the shape of the relevant part of the internal periphery of the structure 1 1.

In use, hot air is blown from the heater 24 via the outlet 30 and around the loop, returning to the heater 24 via inlet 29. By locating the forward and return portions of the duct 38A adjacent one another the amount of heat radiated in use from the duct 38A in the desired region, i.e. around the periphery of Zone 1 of the accommodation space, is increased compared to a single length of duct.

Alternatively, the or each duct 38 may extend from one of the outlets 30, 31 and terminate at a free end, i.e. an end that is not connected to one of the inlets. In Figure 1 , duct 38B has one open end 64 connected to outlet 31 and a free end 66. The free end 66 may be closed, or closable by means of a closable vent (not shown). The duct 38B extends around the periphery of the structure 1 1 , in particular around the periphery of Zone 2. At least one, but typically a plurality of, outlets 70 are formed in the duct 38B between its ends 64, 66. Each outlet 70 may conveniently be provided by forming a respective aperture though the body of the duct 38B. Typically, the outlets 70 are mutually spaced apart in the longitudinal direction of the duct 38B. Preferably, the outlets 70 are positioned on the duct 38B so as to face outwardly from the periphery of the structure 1 1 and/or upwardly from the floor 13. Optionally, any one or more of the outlets 70 may comprise a closable vent (not shown), although it is preferred that the outlets 70 are normally open.

The outlets 70 are located in a distal portion of the duct 38B, the distal portion being separated from the outlet 31 of the heater 24 by a proximal portion of the duct 38B. In preferred embodiments there are no outlets 70, or at least no normally open outlets, in the proximal portion of the duct 38B. In some embodiments, the proximal portion of the duct 38B may include one or more outlets 70, but in any event fewer than are provided in the distal portion of the duct 38B, assuming the outlets are of the same size otherwise of a lower cumulative cross section area. By way of example, the distal portion accounts for up to approximately 50% of the total length of the duct 38B, although more typically it accounts for up to approximately 40%, or up to approximately 25%, of the total length of the duct 38B. This is because if normally open outlets are provided too close to the space heater outlet, insufficient heated air will reach the free end of the duct 38B.

In use, because the proximal portion of the duct 38B is located closer to the space heater 24 than the distal portion, the air flowing through the proximal portion is hotter than the air that reaches the distal portion and, as such, the proximal portion radiates more heat (per unit area) than the distal portion. The outlets 70 compensate for the relatively poor radiation performance of the distal portion by allowing hot air to be blown out of the duct 38B to supplement the radiant heat provided by the distal portion. In preferred embodiments, the configuration of the outlets 70 may be selected such that the distal portion provides substantially the same amount of heat to the surrounding environment as the proximal portion. Alternatively, the configuration of the outlets 70 may be selected to provide a relatively increased or decreased heat output by the proximal portion or one or more respective subsections thereof. Selecting the configuration of the outlets 70 may involve selecting any one or more of the size, shape, location and/or spacing of the outlets 70. It will be apparent that the outlets 70 must be sufficiently large to allow air flow through at a sufficient rate and in a sufficient amount to appreciably supplement the radiant heat while not preventing sufficient hot air from reaching the free end of the duct. Typically, the outlets have a diameter of approximately 5 mm to approximately 50 mm. Optionally, one or more closable vents (not shown) are provided in one or more of the ducts 38, particularly in a duct 38 that is configured to form a loop such as duct 38A. The, or each vent, is preferably provided in the body of the duct between the duct ends and, where there is more than one vent, they my be spaced apart along the length of the duct. The or each vent may be opened or closed, preferably independently of each other but optionally in unison. The vent(s) may be operated manually or by an automated opening/closing device as desired. When the vent(s) are open, the system 22 acts as a blown air system in the vicinity of the open vent(s) and this increases the speed at which the surrounding space is heated.

Preferred systems embodying the invention offer advantages normally associated with wet systems, i.e. being relatively quiet and clean, and providing even heating of the space as well as heating the fabric of the structure, avoiding the disadvantages cost, weight and latency.

The invention is not limited to the embodiment(s) described herein but can be amended or modified without departing from the scope of the present invention.