PL244745B1 - Accumulative heating of houses - Google Patents

Abstract

The project is low-temperature heating of houses. The heating medium is non-toxic air. In the project, heat consumption comes from renewable energy or night electricity tariff. Other energy sources are also possible. For example, waste heat from technological processes. Heating walls can be partition walls or their segments. It is advisable to "glue" the heating wall to load-bearing walls. Underfloor heating is also possible, for example in the bathroom. The solution is characterized by high thermal inertia due to the material and mass of the heating walls. Together with low-temperature heating, it is an economical solution. High inertia is unfavorable if we want to raise the room temperature in an unheated house in a short time. The solution is to make part of the heating wall, in the drawing, from a material with high thermal conductivity, for example aluminum. This heating segment can be disconnected from the installation when the set or similar temperature is reached in the room. The closed circuit installation will be made of plastic. Low temperature heating 35 - 55°C. About 30% less energy consumption (water heating). The aluminum segment can also be used for refrigeration purposes. The steam condensate formed on the wall will not create "fungus". Structure can be beautifying. The Christmas tree shape (V) will allow us to allow the condensate to flow pointwise. Beneficial reduction of humidity. It is necessary to check the economic feasibility of using a portable "cold storage" which would cool circulating air, e.g. liquefied oxygen, through an exchanger.

Description

Description of the invention

Description of the state of the art for home heating:

A well-known solution in the 1950s and 1960s was heating rooms with heated air. The air circulation was not closed. The heat source for the heated air was coal burned in special furnaces. The heated air was transported to the living room through a brick duct in the lower part of the wall.

The air outlet on the wall was protected with a mesh.

Over time, dust and bacteria accumulated in the duct and were blown into the living rooms. The indoor air was dry. It was not a closed circuit. Make-up air was coming from outside.

This solution was short-lived and did not find wider application.

PL 128406 U1 "Induction heater for liquid and gaseous media".

Since in this project we can heat both gas and liquid, it means that the flow of these media can only take place in the pipe. The construction of the radiator is different. This is illustrated in the drawing associated with the project.

PL 34065 B1 "Central air heating" Notification March 14, 1951 "... thin air spaces are used inside the building, constituting air envelopes around the building, connected together to form a closed circuit." Definitely a different solution to the above P.442042 project. This is illustrated in the drawing associated with the project.

The essence of the invention is the accumulation heating of houses containing an induction heater, a fan and ceramic heating walls, in which a segmented induction heater with axial discharge of heated air, heated in a spiral over the entire surface of the heating sheet, is adapted for circulation. In the invention for storage heating of houses, an independent technology for heating air in a multi-segment induction heater and a technology for making segmented heating walls were developed. Both technologies are components of the "Storage home heating" project. Heating is low temperature. The heating medium is air in a closed circuit. Energy consumption comes from renewable energy.

Example of implementation with reference to drawings:

The subject of the invention in an embodiment of an induction heater is shown in Figure 1.

An example of an induction heater with a channel-spiral flow of heated gas is shown in the longitudinal section of the assembly drawing of the heater.

An induction heater is characterized by the following: current is supplied to the resistance spiral (3) of the induction heater via a cable. The current flowing in the spiral (3) generates eddy currents in the ferritic sheet (1), which heats them and thus, through heat exchange, the air flowing in the spiral channels (I). The resistance spiral (3) is separated from the ferritic sheet (1) by insulation (4). The radiator has an axial central discharge of heated air (II) from the induction heaters. Spiral channels (I) made of flat bar sheets (5), flowing around the ferritic sheet (1), allow direct heat removal from the entire surface of the sheet (1).

The induction heater according to the invention can be used for heating purposes and in industries where it is necessary to heat gases for technological processes.

The subject of the invention in an embodiment of heating walls is shown in Figure 2.

An example of the implementation of segmented heating walls is shown in the main projection and in the longitudinal section in the drawing of the heating wall.

Segmented heating walls are characterized by the fact that the heating wall of the house is a ducted, air-heated wall. The heat source is an axial multi-segment induction heater (102) coupled with an axial fan (103).

Air in a closed circuit, flowing into the spiral channels (I) of the induction heater. In the spiral channels of the heater, the air receives the heat generated by the induction of current on the heating plates (1) of individual induction heaters (G). The heated air from the spiral channels (I) flows into the central axial outlet channel (II). From here, it is supplied via installation cables (105) to the heating wall channels (101). In the heating wall, the air releases its thermal energy for heating purposes and part of the heat is accumulated. The amount of heat supplied to individual walls is controlled by switching flaps (104) and by turning on/off the induction heaters that are part of the electronic control.

The circulating air flow takes place under a slight overpressure that allows to overcome the flow resistance in the circulation system (105) and the heating wall (101). Circulation and overpressure are provided by an axial fan (103) connected to the induction heater (102).

Channel ceramic heating walls are walls or their segments (101).

We receive hot air from the induction air heater (102) from renewable energy.

The heating air circulation is closed. The air circulation in the circuit is created by the fan (103).

Each heated house has a cheap electricity-to-heat converter. That is, a spiral-axial induction air heater set (102).

Heating walls are characterized by high thermal inertia due to the ceramic material and the mass of the wall.

Once properly constructed, the heating installation is sterile, maintenance-free, financial outlays are low, and thermal inertia is high. This, in turn, can be compared to an ideal ecological tiled stove in which there is no need to burn coal or remove ash, there is no unnecessary chimney and its systematic cleaning. We do not have an ecological problem with CO2 released into the atmosphere.

With a large surface area of heating walls, we will use high-efficiency low-temperature circulation heating. We have a large heat exchange surface of the heating wall, we have a large thermal inertia of the wall, which will allow us to use the electricity from solar panels to heat the circulating air. Due to the high inertia of the heating wall, lack of electricity supply at night is not a problem. If there is insufficient electricity from solar panels, it is possible to supplement it with electricity from another source.

Drawings representation:

Items in the attached drawing 1. Induction heater

Ferritic heating sheet

Outer sheet metal

Resistance spiral

Insulation

Spiral sheet (channel)

Closing plate

I Air inlet

II Air outlet

Items in the attached drawing 2. Heating walls

101 Ceramic heating walls

102 Induction heater. Figure 1

103 Axial fan

104 Switch flap

105 Installation cable

106 Insulation

107 House wall

Claims (3)

1. Accumulatory heating of houses containing a radiator (102), a fan (103) and ceramic heating walls (101), characterized in that a segmented induction heater with a central axial discharge of heated air (II), heated in a spiral over the entire surface of the sheet, is adapted for circulation. heating (1). 2. Heating according to claim 1, characterized in that heated air flows through the channels in the center of the ceramic heating walls (101) in a closed circuit. 3. Heating according to claim 1, characterized in that it is low-temperature.