DE10205624A1 - Hot air distribution modules, for floor/wall heating, are assembled into the required structure using a single hot air supply with a controlled outflow to give the desired heating level - Google Patents

Abstract

The hot air distribution system is composed of modules (1) which are assembled together in a pattern for the required structure to distribute hot or cold air. The module has an air entry opening (2) for the air inflow (3) into a direct heating flow (4). Outflow openings (6) give further distribution flows (5). The direct heating of a room space is through a flat sliding grid (8), set by a control (7).

Description

The present invention relates to a heater with a new one inventive "hot air distribution system for direct heating, Underfloor heating and wall heating. "

Heating is heated air that is used to heat a room. In the Today's heat is mostly generated by electricity, oil, gas or others Solid fuels generated. Warm air technology was already in the 2000 years ago Roman times known. Back then there was surface heating in the floor and Wall area. Unfortunately, this room heating was cumbersome to use. That is why this heating technology became essentially general only in thermal baths Usage. This warm air heating was largely neglected or was insufficient due to simple warm air distribution, uneconomical and continued without comfort. Just think of the individual Exhaust flaps of warm air ducts that have large and disruptive Soundscapes. A regulated supply of warm air was therefore not an option think.

Today, powerful warm air blowers are used in a variety of ways in large buildings. This Air blowers cause large dust swirls and often contribute to colds through train-like appearances.

The warm air distribution system for direct room heating with floor heating and hiking warming is new to the invention and completely eliminates the old disadvantages on.

Many advantages are now available:
A quick and uncomplicated modular structure of the system saves costs and expensive maintenance work.

• 1. Mittels Regelung kann Warmluft direkt dem Raum zugeführt werden. Dies trägt bei Auskühlung zur schnellen Erwärmung bei.
• 2. Im Normalbetrieb wird die Warmluft zur Fußbodenerwärmung weitergeleitet und von dort über ein weiteres Verteilerelement zur Wanderwärmung geführt.

There is only one supply pipe from the warm air generator. Before entering the distribution system, the warm air is regulated by means of a thermostat or by manual control and passed on to a distribution element. This element has two functions.

• 1. Warm air can be fed directly into the room by means of control. When cooling down, this contributes to rapid heating.
• 2. In normal operation, the warm air is passed on to the floor heating and from there via a further distribution element to the heating.

Thanks to thermal buoyancy, the warm air travels across the entire area and is noiseless through the whole distribution system.

It creates a pleasant, even radiant heat from the floor and wall reached. Mold at the corners can no longer develop.

This warm air distribution system is suitable for the entire residential construction, Offices, halls, swimming pools and many other functional buildings.

The module structure allows the omission of the building restrictions Underfloor heating or alternatively wall heating.

use function

Ideally, fresh air is used by means of pipes and fans in the Floor area led. This air is caused by natural global warming Warm air generator supplied and adjusted to the desired temperature and to the forwarded distribution system according to the invention. This can be an additional benefit System in summer, with the warm air heater switched off, for cooling rooms be used. An upstream cooling system takes over the temperature Regulation. The dreaded colds like conventional air conditioners stay out.

Function and structure of hot air heating according to figures

Fig. 1 the module is placed at the beginning of the inner wall and the beginning of the raw floor and serves as a distributor element of the incoming warm air from the warm air generator. Manual control on the distributor element allows direct heating using warm air in a cooled room. Rapid heating is guaranteed. In normal operation, the hot air is passed on from the distributor to the blanket cavities on the floor.

Fig. 2 the structure of the underfloor heating: Handy plastic plates or thin sheets, which are provided with deep embossed hollow knobs, are processed as element panels. These are laid out overlapping in the room. The whole area must have a seamless connection between the figures. 1 and 3 result. These distribution elements are each as long as the width of the premises. In this way, the hot air flow can be absorbed evenly over the entire surface and distributed. The nub heights of the plates need not be higher than 20 mm. At this height, electrical cables for switches and sockets can also be laid between the knobs. The warm air flow is not hindered by this. The passage of warm air only requires a few mm in height. After laying the slab, the screed can be applied immediately. The deep embossed hollow knobs are now supporting the screed slab due to the backfilling. On the underside there is a cavity for the warm air to flow through.
To quickly dry the screed, warm air can be used immediately via the distribution system. This eliminates time-consuming waiting at the construction site. The built-in panels are at the same time a lost formwork of the screed and a barrier against the ingress of moisture. Resonance absorbers in the cavity on the underside result in good impact sound insulation. Break-ins due to heavy loads or even cable drilling can be repaired in the local area without great effort.
Another possibility is the renovation of old buildings and timber construction. Due to the low weight and the low installation height, the listed wall heating (in Fig. 4) can also be used as underfloor heating.

Fig. 3 the module is installed at the end of the underfloor heating (in the corner area) and at the beginning of the wall heating joint-tight and serves as an element for collecting the incoming warm air from the end of the underfloor heating and is responsible for the continuation to the wall heating.

Fig. 4 the construction of the wall heating is carried out in dry construction and is placed directly on the raw wall.
Above the corner element (see Fig. 3) are attached to the wall in the longitudinal process, by dowelling, nailing or gluing, cross-perforated wood profiles or sheet metal profiles. The cross perforation is important, because this way the warm air can function evenly and crosswise upwards. Next, these profiles are seamlessly covered with plasterboard, particle board or other materials. This process can be done by screwing or gluing. The wall heating is inexpensive and quick to manufacture thanks to the profiles and plates. The cross perforation of the substructure (profiles) allows electrical cables for switches and sockets to be inserted without effort. The height of the substructure is determined by the possible insertion of power cables. In the test, a height of 20 mm was sufficient to ensure uniform heating of the wall surface due to thermal buoyancy. Time-consuming and expensive plastering work for wall heating is no longer necessary.

Fig. 5 the last module sits as a collecting element at the end of the wall heater and closes off to the ceiling. Here, the warm air is collected across the entire width of the wall heating and released to the exhaust air outlet.

Fig. 6 shows summarily shows the construction of the Warmlufiverteilung.

The invention is described in more detail with reference to the drawings and the list of reference symbols. The subclaims are detailed in FIGS . 1 to 5.

Fig. 6 shows the structure of the finished module Warmlufiverteilung.

Fig. 1 shows a module which is also appropriately referred to as a distributor element 1. The beginning shows an air inlet opening 2 . The arrows 3 indicate the input air flow. The further arrows 4 indicate the air flow of direct heating. The outlet opening 6 serves for the further distribution of the air flows, as indicated by the arrows 5 . The direct heating of a room is preferably carried out via displaceable flat grids 8 . These grids are controlled by the controller 7 .

Fig. 2 shows the structure of the underfloor heating.

A top view shows the screed plate 9 and the element panel 10 underneath with the deeply embossed hollow knobs 11 .

A front view shows in section the screed plate 14 with the full knobs. Underneath the element panel 15 , the deeply embossed hollow knobs are clearly visible.
A bottom view shows the screed plate 17 with the associated full knobs 16 . The element panel 18 with the hollow knobs 19 below shows the warm air 20 flowing therebetween.

Fig. 3 shows a distributor element 21, the air inlet opening 22 and an air outlet opening 23 adduced. The arrows 24 mark the air inlet and the arrows 25 point the way of the air outlet.

Fig. 4 demonstrates the structure of the wall heating.
Profiles 27 are screwed or glued onto the raw wall 26 and covered by a paneling plate 28 . This is done by means of screws 29 . The arrows 30 indicate the warm air path.

Fig. 5 shows the final distribution member 31 of the system.
In the arrangement there is an air inlet opening 32 and an air outlet opening 33 . The arrows 34 show the path of the air entry. The arrows 35 lead the way of the exhaust air.

Fig. 6 demonstrates the entire structure of the warm air distribution system.
The system is connected via a supply air pipe 36 arriving from the heat generator. The distributor element 38 shows the opening for the air inlet 37 . Direct heating 40 is controlled via controller 39 . Then comes the underfloor heating 41 and, further expanding, follows a distributor element 42 which also connects the wall heating 43 . The last distributor element 44 releases the exhaust air 45 last. The inner wall 46 and the unfinished floor 47 and the outer wall 48 form the framework of the distribution system. Reference list 1 distributor element
2 air inlet opening
3 arrows
4 arrows
5 arrows
6 air outlet
7 direct heating controller
8 air outlet grilles
9 screed
10 element board
11 hollow knobs
12 arrows
13 arrows
14 screed
15 element panel
16 screed knobs
17 screed
18 element panel
19 hollow knobs
20 arrows
21 distributor element
22 air inlet opening
23 air outlet opening
24 arrows
25 arrows
26 raw wall
27 profiles
28 paneling panel
29 screws
30 arrows
31 distributor element
32 air inlet opening
33 air outlet opening
34 arrows
35 arrows
36 supply air pipe
37 air intake
38 distributor element
39 air regulator
40 direct heating
41 underfloor heating
42 distributor element
43 wall heating
44 distributor element
45 exhaust air
46 inner wall
47 raw floor
48 outer wall

Claims (3)

1. Going that there is not yet a system and therefore one Represents novelty. 2. Based on claim 1 that the system consists of individual modules that are interchangeable with each other in grid dimensions and thus a simplification represents during construction. 3. Continuing according to claim 1 and 2 - comes the double benefit as Heating system and cooling system added.