The invention relates to collapsible car shelter consisting of metal brackets in contexts surrounded by fabric awning. Folding car roofs do not exist. Car shelters that exist today are permanent construction in concrete or steel structures, which are erected outdoors, particularly in the areas of residential yards, and are constituents of the soil, permanently bonded to the ground. The advantage of this invention is that the car cover is a foldable structure which can at the discretion of the owner be placed within a cased frame to the ground by retraction, and thereby it is possible to release the area of the court or the outdoor area, the covering is collapsible structure before collapse and which can thus be attributed to any other use. In the present invention, all of the individual parts, mobile and fixed, can be placed within a cased Π- shaped metal box in the ground, hich is covered after the collapse of the invention with metal caps on the amount of floor space.

The presentation and the description of the invention are below with reference to accompanying drawings and corresponding references to the

corresponding numbers.

Figure 1 shows the invention in full perspective development, showing the ground cased metal frame Π-shaped box, with folding cover inside it, after the full retraction, and the mechanism of the shelter.

Figure 2 shows the invention in full perspective development

Showing the ground cased metal frame Π-shaped box the collapsible shelter in full development outside of the box and above the ground and the mechanism of the cover.

Figure 3 shows a longitudinal section of the axis of symmetry, showing, according to the invention, the cased on the ground metal frame Π-shaped box the collapsible shelter in full development outside of the box and above the ground and the mechanism of the shelter

Figure 4 shows in detail the sliding guide of the metal frame and auxiliary lifting disk..

Figure 5 shows in detail the mechanism that sets the mechanisms of the lifting framework caps in motion. Figure 1 shows the ground cased metal frame Π-shaped box (1). It presents three caps (16) which cover the canister (1 ) after the collapse of the enclosure (shelter) It. presents eight solid metal arms (6) per side of the enclosure to retract into the metal box (1), where the arms (6) according to the invention are the basic skeleton after their full growth above the ground. The arms (6) are eight per side and a total of sixteen. The eight arms (6) per side, at full development, form each one with the next or previous arm (6) an angle of twenty-two and a half degrees and form together in their full development a semicircle one hundred and eighty degrees. Figure 1 shows the nine Π-shaped metal frames (7), on which the metal brackets are implemented. (6). The metal frames (7) are nine, implemented to the arms (6) extrapolate them so that they can develop the final length which can be varied, to be proportional to the type and length of each vehicle.. It presents the lifting guide (5) and a uniform consecutive development of the arms (6), with which a uniform and consecutive development of the arms works. (6) The lifting guide (5) composes the first arm (6) the next four arms firmly

implemented on it. (6) from fixed holes, while the remaining four arms (6) slide into the guide grooves (5), which is progressively larger, to maintain the constant angle of 22.5 degrees between the arms (6) in their growth. The lifting guides (5) are totally two, each on either side of the invention. It displays the motor (2) which with the interposition of the reducer (3) rotates two lifting guides (5) of the nine arms (6), where the motor (2) is located in the open side of the box (1), as this is illustrated in Figure 1 and is activated by remote control. It displays the sliding guide (12) within the metal frame - box (1 ), which ensures a smooth and uniform output and the growth of the last four outgoing frames (7) from the metal frame - box (1 ), and the smooth and uniform placement, storage and application of these four frames (7) during the collapse within the frame - box (1), maintaining a constant distance between the frames (7) thereof. The sliding guides (12) are two, each to each side of the invention. It presents the central axis (4), which sets the two lifting guides into motion by the underground movement. (5). It displays the lifting mechanism (14) of the two side caps (16) to open and close both side caps (16) of the metal frame - box (1). It displays the lifting mechanism (15) of the middle cap (16) which opens and closes the middle lid (16) of the metal box (1).lt shows the position of the mechanism (13) which drives the mechanisms (14) and (15) to move the caps (16). The nine frames (7) of one side are joined to the nine frames (7) of the other side in nine angular profile (8) per side, forming nine metal Π-shaped frames. (7) The angular profiles (8) are nine per side and a total of eighteen. The engine (2), through the gear (3) sets metal lifting guide into motion in which the guide (5) rotates, so that it can successively compose, lift and allocate the eight radial arms (6). It shows the auxiliary lifting disk (11) which is driven via a chain (9) and tightrope (10) with the same frequency of rotation with the lifting guide (5). The auxiliary disk (11) assists the movement of the last four outgoing frames (7) by pushing the respective projections with an axis bearing system. (18).

Figure 2 shows the nine metal arms (6) of the enclosure (shelter) in full development outside of the metal box, which (6) according to the invention are the basic skeleton after their complete growth above the ground. It presents the caps (16) which cover the metal box (1) after the development of the enclosure (shelter). It presents eight solid metal arms (6) per side of the enclosure in development outside of the metal box. (1). It presents nine U- shaped metal frames (7), in which the metal arms are implemented. (6)lt displays the lifting guide and the uniform sequential development of the arms. (6). It displays the lifting motor (2) of eight arms (6). It displays the sliding guide (12) in the metal frame - box (1), which ensures smooth and uniform output and growth over the past four outgoing frames (7) from the metal frame - box (1), and the smooth and uniform placement, storage and application of these frameworks (7) during the collapse within the frame - box (1). It presents the central axis (4), which sets into motion both(5) lifting guides of the eight arms(8) by underground (6). It presents the mechanism (13) which actuates the actuators (14) through the bars and (15) the caps (16) of the frame - box (1). The nine metal frames (7) of one side are joined to the nine metal frames of the other side (7) into nine angular profiles (8) per side, forming nine U- shaped metal frames. (7).

Figure 3 shows a Π-shaped metal box incased in the ground. (1). It presents nine metal frames (7) on each side of the enclosure in full development which the metal arms are implemented. (6) It presents the lifting guide (5) and the uniform sequential development of the arms (6). It displays the sliding guide (12) within the metal frame - box (1 ). It displays the auxiliary lifting disk (1 ).lt presents the mechanism (13) which sets the actuators into motion (14) and (15) of the caps (16) of the frame - box (1).

Figure 4 shows in detail the sliding guide (12) with the four sliding grooves, which have a special configuration so that the last four frames to slow and not entrained by the movement of the foregoing and to start only when appropriate force exerted by the lifting guide (5). It also shows in detail the auxiliary lifting disk (1 1), collaborating with the sliding guide ( 2) achieves smooth growth and collapse of the last four frames (7).

Figure 5 shows in detail the mechanism (13) consisting of a metal plate disk (17) which rotates due to the main axis (4), which in turn transmits the movement to the cam (18) to transmit motion to mechanisms (14) and (15) the lifting of the caps (16) of the frame - box (1).

Figure 6 shows in detail the lifting mechanism (14) of the side caps. There are two such mechanisms for lifting each of the two side panels.

Figure 7 shows in detail the lifting mechanism (15) of the back cap of the frame box (1). There are two such mechanisms for lifting of the back cap and are driven by their respective lifting devices (14) of the side caps.