RU154692U1 - DEVICE OF TWO-SIDED IMAGE DEMONSTRATION (TETRA-LENGTH) - Google Patents

Abstract

1. The device is a two-way demonstration of images (tetravision), comprising a housing, a drive mechanism and a storage medium of graphic information made of square prisms arranged in a row and adjacent to each other, mounted on poles inside the housing and able to rotate around its axis using a drive mechanism, characterized the fact that the faces of each square prism are made movable in the radial direction and with the ability to set the relative position of the faces of adjacent prisms, allowing the prisms to be rotated with extended faces through the sides of adjacent prisms with inwardly displaced faces. 2. The device according to claim 1, characterized in that it has a vertical arrangement of prisms, all faces of the prism have stiffening ribs on the inside that end with narrowed protrusions at both ends to which the adapters are bolted, while all the adapters are the same and have one horizontal through hole for the tail of the cross and the recess from the end in the form of a fragment of a ring for removable roller clamps to hold the outer edges of the prisms from radial displacement or under roller pushers on the rods of the drive mechanism for moving the inner faces of the prism on the tails of the crosspiece, while the cores of the crosses are rigidly attached to the half shafts fixed in the bearing supports, which in turn have a bolt fastening to the housing, the upper and lower half shafts being interconnected by intermediate shafts by means of a detachable connection, the rotation of the prisms in sequence through one and their fixation is carried out using fixed on the axles, with vert�

Description

The device for two-way image demonstration (tetravision) refers to electromechanical devices and is intended to demonstrate any graphic information, and can be used for advertising and other similar purposes.

A technical solution is known according to the patent of the Russian Federation No. 2165649 “Advertising installation” in which a field of trihedral prisms mounted in supports with the possibility of simultaneous rotation around its axis using a rotary mechanism is used as a graphic information carrier. The rotation is carried out using a drive shaft with drive disks mounted on it with protrusions and slots that interact with the rays of the driven sprockets mounted on the axes of the prisms. When the shaft rotates, the prisms rotate, or all at the same time, or in two halves, according to the design features of the drive shaft.

The disadvantages of this solution are the impossibility of demonstrating more than three images, one-sided viewing, and the need to install prisms with large technological gaps between adjacent prisms, which significantly affects the quality of the displayed images.

The problem the utility model aims to solve is to increase the information capacity of the demonstration device, provide a two-way view, and also improve the quality of the images displayed.

The technical result from the use of the proposed device for two-way image demonstration (tetravision) is to increase the information capacity of the demonstration device to four images, the possibility of two-way viewing, as well as improving the quality of the displayed images, since the gaps between the prisms are significantly reduced.

The above result is achieved due to the fact that in the device of two-sided image demonstration (tetravision), the graphic information carrier is made in the form of square prisms adjacent to each other, forming two demonstration fields with external visible faces on both sides of the device, the prisms are fixed on the supports inside the case and are capable of rotate around its axis by means of a drive mechanism, the edges of each square prism are movably fixed on two crosses with fixation from the radial displacement of the external visible faces, but with the possibility of simultaneous movement of the inner faces of adjacent prisms to enable parallel rotation of 90 degrees of all prisms with spread faces through the sides of adjacent prisms with inwardly shifted faces, so that all prisms are rotated in sequence through one in two steps with a drive mechanism that performs twice and the rotation of the prisms, and the movement of the inner faces of the prisms.

The essence of the utility model is illustrated by drawings, where:

In FIG. 1 - General schematic front view of a fragment of a device with a drive mechanism.

In FIG. 2 - Top view of the device from the section line Α-A (without mounting frame).

In FIG. 3 - Layout of prism faces with adapters (isometry).

The device as shown in FIG. 1, FIG. 2 and FIG. 3, comprises a rectangular housing 3 with a through opening, inside of which, in a row vertically adjacent to each other, all rectangular prisms are located, the external visible edges 10 of which on both sides are demonstration areas of the device. All faces of the prism have stiffening ribs on the inside, ending with narrowed protrusions at both ends, to which adapters 6 are bolted 5, while all adapters are the same and have one horizontal through hole 30, aligned with the corresponding hole on the protrusion of the prism face, under the tail of the cross 7, and a recess 12 from the end in the form of a fragment of a ring for removable roller retainers 15 mounted on a bar 16 to hold the outer faces of the prisms 10 from radial displacement, as well as under the roller pushers 13 on bias the tangs 26 associated with the drive mechanism 2, driven by an electric motor with a gear 1, to move the inner faces of the prism on the tails of the cross 7, while the cores of the crosses are rigidly attached to the axles 18, mounted in the bearing bearings 17, which in turn have a bolt mount to the housing 3, and the upper and lower half shafts 18 are interconnected by intermediate shafts 11 by means of detachable joints, alternately turning 90 degrees of the prisms in sequence through one, as well as fixing them from radial rotation, is performed using fixed on the axles 18, with a vertical offset through one, four-beam sprockets 19 and 20, interacting with two rotary rods 21 and 22 connected with the drive mechanism 2, located and able to move horizontally in the holding 25 and supporting 29 rollers with two sides of the four-beam sprockets 19 and 20 and in close proximity to them, and the displacement of the inner faces 9 is carried out by roller pushers 13 attached to two pairs of biasing rods 26 located nearby, but with the ability to move towards each other in the guide rollers 27. All the rollers holding the rotary rods 21 and 22, the biasing rods 26, as well as the removable roller clips 15 on the bar 16, are attached to the mounting frame 4, which in turn has a detachable bolt fastening to the housing 3 at the top and bottom of the device. To ensure that the prisms rotate 90 degrees, the rotary rods 21 and 22 have corresponding cutouts 28 for the rays of four-beam sprockets 19 and 20, and at a commensurate distance from the cutouts 28, movable stops 23 and 24 are fixed, made with the ability to push the corresponding rays of the sprockets during rotational the movement of the rotary rods 21 and 22 and freely move them in the opposite direction, which allows you to rotate the four-beam sprockets 19 and 20 by an angle sufficient for the rays of the stars to enter the cutout 28 on the rotary rods 21 and 22. Each pa a set of biasing rods 26 is mounted on the mounting frame 4 on two sides of the axle shafts 18 within the width of the adapter 6 and has two adjacent rods moving towards each other in the guide rollers 27. The rods moving in the direction from the drive mechanism 2 are attached directly to it, and rods moving in the opposite direction are driven through swinging levers 14 on the transmission shafts 8 from two sides of the device, one shoulder of which is movably attached to the rods moving in the direction from the drive mechanism 2, and the opposite shoulder to the rods in the opposite direction. The transmission shafts 8 also drive two similar pairs of bias rods 26 on the opposite lower side of the device with two swinging levers 14 having a corresponding fastening to the lower bias rods 26.

The device for two-way display of images (tetravision) of FIG. 1 and FIG. 2 works as follows. In the demo mode, for the illustrated variant, before the start of the four-phase rotation cycle of the prisms, the external visible faces 10 on both sides of the device are always on the tails of the crosspieces 7, for all odd prisms the internal faces 9 are also apart, and for all even prisms they are shifted inward. Such a relative position of the faces of adjacent prisms, as shown in FIG. 3, allows prisms with spread faces to freely rotate through the sides of adjacent prisms with inwardly displaced faces. All four-beam sprockets 19 and 20 have constant contact contact by two beams with their corresponding rotary rods 21 and 22. After turning on the electric drive 1 of the drive mechanism 2 in the first phase of the prism rotation cycle, both rotary rods 21 and 22 begin to move in the direction from the drive mechanism 2 the odd prism drive 22 (lower in Fig. 2) equally for all odd prisms with a movable stop 23 pushes the right beam of the four-beam sprocket 20, providing its slight rotation sufficient for the left beam to enter the cutout 28 otnoy rod 22. Further movement of the pivot rod 22 located in the recess 28, the rotary rods 22, a four-beam sprocket 20 will cause its smooth rotation, and with it the whole prism 90 degrees. After the beam leaves the cutout 28 on the rotary bar 22, it stops, again providing contact contact with the two beams of the four-beam sprocket 20, reliably fixing the odd prisms in the demonstration position. Simultaneously with the above process, the rotary rod 21 of the drive of even prisms is the same for all even prisms (the upper one in Fig. 2), moving, it allows moving, having risen, the movable stop 24 through the left beam of the four-beam sprocket 19 due to the fact that the opposite side, not pushing it is inclined with respect to the beam of the four-beam sprocket 19. In this case, the cutout 28 on the pivoting rod 21 moves beyond the limits of the right beam. The pivot rod 21 stops, also providing a contact contact to the two beams of the four-beam sprocket 19 of even prisms. Immediately after this, the second phase of the rotation of the prisms starts - a change in the position of the inner faces 9, that is, on the odd prisms, the inner faces are displaced on the tails of the cross 7 in the prism, and on the even ones outward in the rotational position, due to the impact of the roller pushers 13 fixed on them biasing rods 26 in the upper and lower parts of the device. After stopping the inner faces 9 in the corresponding extreme positions, the third phase begins, the rotation of even prisms. Both swing rods 21 and 22 begin the reverse movement. The even prism drive rod 21 equally for all even prisms (the upper one in Fig. 2) with movable stops 24 pushes the left beam of the four-beam sprocket 19, providing its slight rotation sufficient for the right beam to enter the cutout 28 on the rotary rod 21. Further movement of the rotary rod 21 s being in the cutout 28 of the rotary rod 21, the beam of the four-beam sprocket 19 will lead to its smooth rotation, and with it the entire even prism by 90 degrees. After the beam exits the cutout 28 on the pivot rod 21, it stops, providing contact contact with the two beams of the four-beam sprocket 19, reliably fixing the even prism in the demonstration position. At the same time, the rotary rod 22 of the drive of the odd prisms equally for all odd prisms (lower in FIG. 2) moving allows you to move, having risen, the movable stop 23 through the right beam of the four-beam sprocket 20 due to the fact that the opposite non-pushing side of the movable stop 23 is inclined along relative to the beam of the four-beam sprocket 20. In this case, the cutout 28 on the pivot rod 22 moves beyond the left beam, and the pivot rod 22 stops, also providing contact contact with the two beams of the four-beam sprocket 2 0 odd prisms. After this, the last fourth phase starts - the return of the position of the inner faces 9 to its original position, that is, on even prisms, the inner faces 9 are displaced on the tails of the crosses 7 inward of the prism, and on the odd ones outward into the rotational position due to the action of the roller pushers 13 on the biasing ones rods 26 in the upper and lower parts of the device. At this point, the prism rotation cycle is over. After that, the electric drive 1 of the drive mechanism 2 is stopped for the duration of the demonstration of images. The design provides, but not shown here, the drive control module 1, configured to set the stop time of the drive 1, which recognizes the initial position of the drive mechanism 2 and stops the drive 1 for the duration of the image display.

Thus, the device (tetravision) fully implements the proposed utility model for two-sided demonstration of images, and allows to significantly increase the quality and volume of the displayed graphic information. The use of devices based on this method of demonstration for advertising purposes will double the visual audience through a two-way review and, accordingly, increase the effective time of demonstration of each advertising image.

Claims (4)

1. The device is a two-way demonstration of images (tetravision), comprising a housing, a drive mechanism and a storage medium of graphic information made of square prisms arranged in a row and adjacent to each other, mounted on poles inside the housing and able to rotate around its axis using a drive mechanism, characterized the fact that the faces of each square prism are made movable in the radial direction and with the ability to set the relative position of the faces of adjacent prisms, allowing the prisms to be rotated with spread faces through the sides of adjacent prisms with inwardly displaced faces. 2. The device according to claim 1, characterized in that it has a vertical arrangement of prisms, all faces of the prism have stiffening ribs on the inside that end with narrowed protrusions at both ends, to which the adapters are bolted, while all the adapters are the same and have one horizontal through a hole for the tail of the cross and a recess from the end in the form of a fragment of a ring for removable roller clamps to hold the outer edges of the prisms from radial displacement or under roller pushers on the rods of the drive mechanism for moving the inner faces of the prism on the tails of the crosspiece, while the cores of the crosses are rigidly attached to the axles fixed in the bearing bearings, which in turn are bolted to the housing, the upper and lower axles being interconnected by intermediate shafts by means of a detachable connection, alternating rotation prisms in sequence through one and their fixation is carried out using fixed on half shafts, with vertical displacement through one, four-beam sprockets interacting with two turns GOVERNMENTAL bars located on both sides of the stars in the immediate vicinity, and the displacement of the internal faces of the executed roller tappets, attached to two pairs of biasing rods arranged side by side, but with the ability to move towards each other. 3. The device according to p. 2, characterized in that to ensure the rotation of the prisms on the slewing rods there are corresponding cutouts for the rays of four-beam sprockets, and at a distance from the cutout corresponding to the distance between the rays, movable stops are arranged to push the corresponding rays of the stars during the rotational movement of the rotary rod and freely move it in the opposite direction, allowing you to rotate the sprocket at an angle sufficient for the beam of the star to enter the cutout on the rotary rod. 4. The device according to p. 2, characterized in that two pairs of bias rods with roller pushers are fixed on two sides of the axle shafts within the width of the adapter and have a kinematic connection with a similar pair of bias rods mounted on the opposite side of the housing through two transmission shafts, located on the sides of the device.

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