GB2457088A

GB2457088A - Temperature control system for a building

Info

Publication number: GB2457088A
Application number: GB0801978A
Authority: GB
Inventors: Andrew Thomson
Original assignee: Ultraframe UK Ltd
Current assignee: Ultraframe UK Ltd
Priority date: 2008-02-04
Filing date: 2008-02-04
Publication date: 2009-08-05
Also published as: WO2009098440A1; GB0801978D0

Abstract

A temperature control system for a building 10 comprises passing air through at least one passage 12 between two panels/surfaces 14, 16 associated with the building 10 with the air being arranged to absorb heat to either take away heat or to provide heat for the building 10. Passage 12 may be between glazing panes or a surface of the building and a cladding sheet, which may be glass. Building 10 may be a conservatory and the passage 12 provided by double glazing windows and/or the roof. Located in the ridge 58 of the building 10 may be a circular roof ridge member 30 provided with a rotary air flow diverter 42 having three vanes 44 for diverting heated air away from or into the building 10 via apertures 40A - 40C. Diverter 42 may be rotated by a hand operated lever or by an electric motor. Air flow through passage 12 may be forced by a variable speed fan. A valve 70 may control air entering the passage 12 from inside or outside (fig 7) the building 10. One or more vents 72 may be provided for pressure equalisation.

Description

Title: Temperature control system

Description

This invention concerns a temperature control system and, in particular but not exclusively, a temperature control system for conservatories.

Conservatories provide bright attractive rooms but because of the amount of glazing in the walls and roofs suffer from overheating in warmer weather especially with direct sunlight and heat loss in cooler weather. In warmer weather heat can be trapped in a conservatory requiring ventilation to create a more pleasant environment, such as by opening of windows/doors and/or provision of fans.

In cooler weather heat escapes through the conservatory windows and roof, so that some form of heating is required to create a pleasant environment.

Ventilating and heating systems currently used are not environmentally friendly due to their use of power, such as electrical power.

There is a need for a system for controlling the temperature inside a conservatory or indeed other building structures that is environmentally friendly According to the invention it is proposed that a building have at least one area at its surface that provides a passage along that surface for air moving along that passage to absorb heat either to take the heat away or to provide heat for the building.

Preferably the passage is provided between glazing panes but may be between a surface of the building and a suitable cladding sheet, which may be of glass. For a conservatory the invention may utilise double-glazing of windows and/or the roof to provide the passages for airflow to absorb heat from inside and/outside the conservatory. For other building structures the passage may only absorb heat * . * S S * S. * * S. * *

S

S IS.

from outside the building if sited on a roof or against a supporting wall. However, windows of a building structure may absorb heat from inside and outside the building.

The system of the invention preferably includes means for diverting heated air from the passage either away from or into the building. The former helps to reduce the temperature within the building and the latter helps to increase the temperature within the building.

For a conservatory its ridge may provide a convenient location for the airflow diverting means. One proposal is to provide a roof ridge member able to receive the heated airflow and provided with means for diverting the heated airflow either into or away from the conservatory. The ridge member may be of circular cross-section and having apertures along its length separately open to roof glazing on one or both sides thereof and open to the inside and outside of the roof. Within the ridge member a rotatable airflow diverter is provided, the diverter having vanes arranged to divert airflow from the glazing panel passages to the inside or outside of the roof depending on the orientation of the diverter.

The diverter may be rotated from one position to the other by means of a lever or other hand operated means. Alternatively, electric motor means may be provided to rotate the diverter from one position to the other.

It is further proposed that the system for controlling air flow according to the invention include valve means whereby air flow into the passage between the panes of double glazed windows and roof is drawn from inside or outside the conservatory.

This air may be diverted into or out of the conservatory by the diverter. For example, *.., cooler air may be drawn from outside the conservatory and introduced into the

SS

conservatory, hotter air within the conservatory may be drawn into the window space and diverted out of the ridge or air from the inside of the conservatory may be recirculated within the conservatory.

In addition it is proposed that a conservatory be provided with one or more

S S..

S

closable vents to allow air to escape as fresh air is introduced, to allow air into the conservatory to replace air being diverted out or to maintain a closed system as air is recirculated.

It is further proposed to provide means for forced airflow through the passages, such as a fan associated with the passage. The fan is preferably of variable sped, so that the rate of cooling or heating may be altered as required.

This invention will now be further described with reference to the accompanying drawings, in which: Figure 1 shows schematically airflow through a conservatory window! roof system; Figure 2 is a section through a window or roof showing heat transfer; Figure 3 shows an airflow diverter in a conservatory roof ridge; Figures 4 and 5 show operation of the diverter in hot and cold days; and Figures 6, 7 and 8 show a conservatory having a temperature control system of the invention in three different settings respectively Referring to Figures 1 and 2 of the accompanying drawings, it is proposed that air from outside of a conservatory 10 be channelled through the space 12 between the panes 14, 16 of double glazed windows 18 and roof panels 20, so that heat transfer can take place and either be diverted into the conservatory to warm the conservatory or be expelled to cool the conservatory.

As shown, air entering a double-glazed unit 18, 20 will be subjected to heat generated by the sun on the outer pane 14 and heat from within the conservatory trying to escape from the inner pane when the temperature outside the conservatory is lower than the temperature within the conservatory. The heated air travels then to the ridge of the conservatory roof where an airflow diverter is provided (see Figures 3, 4 and 5 of the drawings. The diverter can be set either to send the heated air into * ** * * S S*. S

S *SS *

the conservatory or to send the heated air away from the conservatory, if it is necessary to cool the inside of the conservatory.

As shown in Figures 3, 4 and 5, a conservatory roof ridge has a ridge member 30 of circular cross-section. The ridge member 30 has on opposite sides channels 32, 34 for retaining roof panes 14, 16 to form a double glazed roof. The ridge member 30 has apertures 40 along its length arranged in four lines A, B, C and D, so that one line 40A is open to the outside of the conservatory, one line 40B is open to the inside of the conservatory and one of each of the other two lines 40C and D opens to one of the spaces between the panes of the double-glazed roof.

Within the ridge member 30 is a rotatable airflow diverter 42. The diverter has three vanes 44, so that in one position the airflow along the double glazed roof can be discharged outside the roof and when rotated through 1200 airflow is diverted into the conservatory.

As shown in Figure 4, on a hot summer's day, for example, airflow through the double glazing of the walls and roof of the conservatory is heated by the sun on the outer pane and by heat form inside the conservatory on the inner pane. This heated air is then discharged from the ridge of the roof in order to keep the temperature within the conservatory from becoming too hot. In other words heat that would be trapped and cause the temperature within the conservatory to rise uncomfortably is dissipated.

In Figure 5, on a cold day again airflow through the double glazing of the walls and roof of the conservatory is heated by the sun on the outer pane and by *:*1 heat form inside the conservatory on the inner pane. This heated air is then diverted SSS $ into the conservatory to heat it.

*.. The ridge member may be formed from an aluminium extrusion and the diverter may also be of aluminium or of plastics material. Rotation of the diverter may be by means of a lever or may be by means of an electric motor.

S 5.

The glazing panes of the windows and roof of the conservatory are preferably about 40m apart. Standard glass may be used for the outside panes but K-glass is preferred for the inside panes.

It may be desirable to be able to alter the rate of airflow through the double-glazing in order to have greater control over the temperature within the conservatory.

To that end, airflow may be fan assisted. The fan is preferably speed variable.

Referring to Figures 6, 7 and 8 there is shown a conservatory having side walls 50 consisting of a low brick wall 52 with windows 54 mounted on the brick wall.

The side walls 50 support a roof 56 having a ridge 58. The windows and roof are both double skinned providing an airflow space linking the windows and roof. The ridge 58 is generally cylindrical along the length of the roof and has opposed upper and lower openings 60, 62 to the inside and outside of the roof respectively. Side openings 64 are also provided in the ridge, which open to the windows on opposite sides of the ridge. Within the ridge is a rotary air flow diverter 66 having three equally spaced fins 68 with sealing beads 69 therealong. The diverter is arranged to air to flow into or out of the conservatory roof as will be explained below.

At the base of the windows there are openings having flaps 70 that are slidable transversely to open and close the openings to the inside or outside of the conservatory. The flaps have sealing beads 71 along their edges that contact the bottom edge of the respective window panes.The brick walls have closable vents 72.

The combination of the diverter 66, flaps 70 and vents 72 form a system that can be used to control the airflow into, out of and within the conservatory in order to *:*:: control the temperature within the conservatory. As shown in Figure 6, the system is

S

i set up for a very hot day, in which the temperature within the conservatory will need to be reduced. The flaps 70 are positioned to allow hot air from the conservatory to enter the air space of the windows to flow up to the ridge where the diverter is set to vent this hot air to the outside. At the same time the air in the conservatory is

S

replaced with cooler air flowing in through the vents 72. The air flow may be forced, if necessary, by suitable fan or pump means.

Turning to Figure 7, on a cooler day the system may be arranged to introduce air via the windows and the roof, so that it is heated before it enters the conservatory.

In this arrangement the flaps 70 are opened to the outside to direct air between the skins of the windows and roof to the ridge, where the diverter is set to divert the heated air into the conservatory. The vents 72 are opened for air to escape as the heated air is introduced.

Finally, in Figure 8 the system is set for a cold day on which it is desirable to recirculate heated air within the conservatory. In this arrangement the flaps 70 are set to open the space between the window skins to the inside of the conservatory, so that air form the inside of the conservatory is directed to the ridge, where the diverter is set to return the air to the interior of the conservatory. The vents 72 are closed to prevent colder air entering the conservatory.

As with the previously described embodiments the ridge member may be formed from an aluminium extrusion and the diverter may also be of aluminium or of plastics material. Rotation of the diverter may be by means of a lever or may be by means of an electric motor.

Whilst the system described above is specific to a conservatory, the principles may be used in providing means for heating or cooling of other buildings by cladding a house wall or roof with glass or a similar suitable material to create an air gap along which air can be fed either to dissipate heat or to provide warmer air to heat the * inside of the building. * ** * S * S.. S

S *SS

S

Claims

Claims: 1. A temperature control system for a building comprising at least one area at its surface that provides a passage along that surface for air moving along that passage to absorb heat either to take the heat away or to provide heat for the building.
2. A system as claimed in claim 1, wherein the passage is provided between glazing panes.
3. A system as claimed in claim 1, wherein the passage is between a surface of the building and a suitable cladding sheet.
4. A system as claimed in claim 3, wherein the cladding sheet is of glass.
5. A system as claimed in claim 1, wherein the building is a conservatory and the passage is provided by double glazing of windows and/or the roof.
6. A system as claimed in any one of claims 1 to 5 including means for diverting heated air from the passage either away from or into the building.
7. A system as claimed in claim 6, wherein for a conservatory said diverting means is located in its ridge.
8. A system as claimed in claim 6, wherein the ridge includes a roof ridge member able to receive the heated airflow and provided with means for diverting the heated airflow either into or away from the conservatory.
9. A system as claimed in claim 8, wherein the ridge member is of circular cross-section and has apertures along its length separately open to roof glazing on one or both sides thereof and open to the inside and outside of the roof.
10. A system as claimed in claim 9, wherein within the ridge member there is a S.. S rotatable airflow diverter, the diverter having vanes arranged to divert airflow from the glazing panel passages to the inside or outside of the roof depending on the * orientation of the diverter. * .. * S S

S

S
11. A system as claimed in claim 10, wherein the diverter is rotatable from one position to the other by means of a lever or other hand operated means.
12. A system as claimed in claim 10, wherein the diverter is rotatable from one position to the other by electric motor means.
13. A system as claimed in any one of claims 1 to 12 having means for forced airflow through the passages.
14. A system as claimed in claim 13, wherein the means for forced airflow is a fan associated with the passage.
15. A system as claimed in claim 14, wherein the fan is of variable speed.
16. A system as claimed in any one of claims 1 to 15, including valve means for the passage, whereby air entering may be from inside or outside of the building.
17. A system as claimed in any one of claims I to 16, including one or more vents for pressure equalisation.
18. A building including a temperature control system as claimed in any one of claims ito 17.
19. A conservatory having a temperature control system as claimed in any one of claims Ito 17.
20. A temperature control system substantially as hereinbefore described with reference to and as illustrated in any of the accompanying drawings.
21. A conservatory substantially as hereinbefore described with reference to and as illustrated in any of the accompanying drawings. * .* * * * * ** * *** * * **** * * * *. * I. * *. * ** * S S S.. S *..

S