BG4282U1 - Heat reflective panel - Google Patents

Abstract

The utility model relates to a heat-reflective panel that reflects heat waves in one direction and transmits them in the other, as it finds application in window blinds, building walls, and various heating or cooling designs. The essence of the utility model relates to a heat-reflective panel, characterised by the fact that it has on the one of its sides a flat surface (1) and on the other side a relief surface (2), as a flat surface (1) and a relief surface (2) are connected by a transparent material. The advantage of the utility model is that it allows heating or cooling relative to the external environment, no matter which side the temperature is higher, and when the panel is inverted the function is changed, allowing summer cooling and winter heating when used for buildings. It works by reflecting and transmitting heat waves that are radiated at atmospheric temperature or higher, including without sunlight.

Description

Field of technique

The utility model refers to a heat-reflective panel that reflects heat waves in one direction and transmits them in the other, having the function of a heater on one side and a cooler on the other side, being applied to window blinds, building walls and in various heating or cooling designs.

Prior art

I am not aware of any prior art with this optical function, the function is like the International Patent Classification (IPC) area F25 solutions, but is entirely by thermal radiation and its optical guidance.

Technical nature of the utility model

The essence of the utility model relates to a heat-reflecting panel characterized by having a flat surface (1) on one side and a relief surface (2) on the other side, such as a flat surface (1) and a relief surface (2) ) are connected by a transparent material. The advantage of the utility model is that it allows heating or cooling relative to the outside environment, regardless of which side the temperature is higher, and when the panel is turned, the function changes, allowing for summer cooling and winter heating when used for buildings .

It works by reflecting and transmitting heat waves that are emitted at atmospheric temperature or higher, including without sunlight.

Explanations of the attached figure

Figure 1 shows a portion of a section according to the utility model, the numbering of which is used in the reference, in the exemplary embodiments and in the claims.

Example implementation of the utility model

An exemplary embodiment of the utility model is a heat reflective panel according to the utility model and claim 1, characterized in that it has a flat surface 1 on one side and a relief surface 2 on the other side, the flat surface 1 and the relief surface 2 being connected through transparent material. The operation of the useful model is as follows: in one direction, the heat waves that fall on a relief surface 2, for the most part pass into the transparent material and are refracted at an oblique angle to the flat surface 1, and a much smaller part is reflected back . Most of the heat waves that have passed through the transparent material undergo total internal reflection from flat surface 1 and return back. In the opposite direction, the heat waves that fall on a flat surface 1, for the most part pass through the panel, and a much smaller part is reflected back. Thus, the heat radiation passes mainly in one direction and non-contact heat transfer takes place.

An exemplary embodiment of the useful model is a heat-reflecting panel, according to claim 3, characterized in that it consists of two panels one on top of the other, each having on one side a flat surface 1 and on the other side having a relief surface 2, as flat surface 1 and relief surface 2 are connected by a transparent material. On both panels, flat surfaces 1 face the same direction, and relief surfaces 2 on both panels represent surfaces of peripheral walls of parallel triangular prisms, the smallest peripheral walls of which lie in a plane that is parallel to flat surface 1 , the bases of the prisms are part of the cross-section of the panels, and the surrounding edges of the prisms of both panels are parallel to each other. Depending on the manufacturing method, each of the panels can be either a monolithic sheet of transparent material with a flat surface 1 and a relief surface 2, or composed of separate prisms that are arranged and mounted to form a flat surface 1 and relief surface 2. The operation of the useful model is as follows: in one direction, the heat waves that fall on the relief surface 2 of one panel, for the most part pass into the transparent material and are refracted at an angle to the flat surface 1, and much more -a small part are reflected back. Most of the heat waves that passed through the transparent material undergo total internal reflection from flat surface 1 and return, and the small part that passed fall at an oblique angle to flat surface 1 onto relief surface 2 of the other panel and undergo total total internal reflection from flat surface 1 of this panel and return back, as well as the small part reflected from relief surface 2. In the opposite direction, the heat waves that fall on flat surface 1 of one panel, for the most part, pass through all the surfaces of the two adjacent ones panel, and a much smaller portion are reflected back. In this way, in one direction of the pair of panels, heat waves pass with negligible reflection and absorption in the transparent material, while in the other direction they do not pass, but are reflected back with negligible absorption in the transparent material. Thus, heat radiation passes in only one direction.

Claims (1)

A heat-reflective panel, characterized in that it has a flat surface (1) on one side and a relief surface (2) on the other side, the flat surface (1) and the relief surface (2) being connected by a transparent material