RU73754U1 - DYNAMIC STAND - Google Patents

Abstract

The utility model relates to means of visual transmission of information, and specifically to dynamic advertising and information stands and demonstration installations that have the ability to change the information provided. What is new is that the drive disks are equipped with finger engagement elements, the driven sprockets are made in the form of trihedral prisms, radial grooves are formed at each of the vertices, and the driven sprockets are mounted with the possibility of interaction of these grooves with the engagement elements of the leading disks. The mechanism of rotation of the prisms is made with the possibility of reverse rotation due to the implementation of each of the rays of the driven sprockets symmetrical with respect to the radial groove at its apex with the possibility of two-sided rotation. The mechanism of rotation of the prisms is made with the possibility of reliable and accurate fixation of the prisms by providing a contact spot between the surfaces of the driven sprocket and the drive disk equal to the face area of the driven sprocket. Elements of additional fixation of structural elements are shown. The technical result achieved by the utility model is to create the optimal mechanism for turning the prisms, by fixing the preset position of the prisms with a significant contact area between the structural elements, as well as in the reverse rotation of the drive sprockets, eliminating their one-sided wear. 1 independent, 5 dependent points, 5 explanatory figures

Description

The utility model relates to means of visual transmission of information, and specifically to dynamic advertising and information stands and demonstration installations that have the ability to change the information provided.

A well-known advertising installation (see RF patent No. 2165649, class IPC G09F 11/02, publ. 04/20/01), containing installed in the supports with the ability to rotate around its own axis of the prism with components applied to their faces that make up a changing advertising image , an engine, a drive shaft, and a prism turning mechanism, including driving disks mounted on the drive shaft with protrusions acting on the rays of the driven sprockets rigidly mounted on the axes of the prisms, while the driven sprockets are mounted with the possibility of simultaneous support act two adjacent beams corresponding to the diametral plane of the drive disk which is formed with an open slot and the placement protrusion on the diametral plane, the distance between the beginning of the lifting projection and the facing protrusion face groove in proportion to the distance between the end portions of adjacent sprockets rays.

A disadvantage of the known installation is the low quality of the advertised image due to unstable movement and fuzzy fixation of the three-beam sprocket. In addition, the rotational movement of the prisms in one direction causes one-sided wear of the rubbing surfaces, which limits their service life, since even slight wear of the contact surface of the sprockets leads to the fact that the size of the protrusion does not allow you to rotate the sprocket for further rotation. Therefore, to ensure the stability of the rotation mechanism, constant monitoring and regulation of the gaps between the ends of the two sprocket rays and the diametrical plane of the drive disk is necessary to ensure the reliability of the installation.

A well-known dynamic stand (see RF patent No. 2219589, class IPC G09F 11/02, G09F 11/00 publ. 12/20/03), which is the closest in its technical essence and the achieved result to the proposal of the applicant and therefore is taken as a prototype comprising mounted in supports with the possibility of rotation around the prism’s own axis with components deposited on their faces that make up a changing advertising image, engine, drive shaft and prism rotation mechanism, including driving disks mounted on the drive shaft made with is engaging in an open groove and interacting on its active face beams rigidly mounted on the axes of the prisms driven sprocket mounted to the support simultaneously contact two adjacent sprocket rays with a diametral plane of the corresponding drive plate. The sprockets are made with rotary stops placed on the end parts of the beams with the orientation of the top of the stop in the direction of rotation of the sprocket. The stand design provides for the possibility of installing “right” and “left” drive disks and sprockets on the drive shaft in various combinations of their location in order to obtain various options for changing the information image.

Known dynamic stand has the following disadvantages:

- during the operation of the stand, there is wear of the grooves of the driving disks and driven sprockets, while their mutual contact occurs pointwise (or along the line), and not along the plane, which violates the fixation of the position of the prisms during the demonstration of advertising images and, therefore, reduces the quality of the displayed Images;

- the presence of “right” and “left” drive disks and sprockets in various combinations of their location not only leads to one-sided wear of the contacting elements, but also does not provide a reverse prism rotation mode, and the need to have two sets of these parts increases the cost of manufacturing the stand, requires his readjustments.

This useful model solves the problem of increasing the stability and clarity of the advertising

information image throughout the entire life of the device, increasing reliability and expanding the functionality of the stand.

The technical result achieved in solving the problem lies in creating the optimal mechanism for the rotation of the prisms, by fixing the preset position of the prisms with a significant contact area between the structural elements, as well as in the reverse rotation of the drive sprockets, eliminating their one-sided wear.

The problem is solved in that the drive disks are equipped with engagement elements in the form of a finger, the driven sprockets are made in the form of trihedral prisms, radial grooves are formed at each of the vertices, and the driven sprockets are mounted with the possibility of interaction of these grooves with the engagement elements of the drive disks. The mechanism of rotation of the prisms is made with the possibility of reverse rotation due to the implementation of each of the rays of the driven sprockets symmetrical with respect to the radial groove at its apex with the possibility of two-sided rotation.

The mechanism of rotation of the prisms is made with the possibility of reliable and accurate fixation of the prisms by providing a contact spot of the surfaces of the driven sprocket and a diametrical plane of the drive disk equal to the face area of the driven sprocket.

The master disk is equipped with a half-disk segment, made with the possibility of interaction with the response groove in the form of a segment based on the driven sprocket with additional fixation from mutual displacement.

The engagement elements of the driving disks are placed with a sequential angular displacement around the circumference of the finger relative to the finger of the previous disk.

The driven sprocket is provided with a latch configured to interact during rotation with the counterpart of the drive disk.

The analysis of the main distinguishing features showed that:

- supplying the drive disks with engagement elements in the form of a finger, the implementation of driven sprockets in the form of trihedral prisms, radial grooves are formed at each of the vertices, as well as the installation of driven sprockets with the possibility of interaction of these grooves with the engagement elements of the driving disks, ensured reliable and smooth operation of the rotation mechanism prisms

- the implementation of each of the rays of the driven sprockets symmetrical with respect to the radial groove at its apex with the possibility of two-sided rotation provided an extension of the functionality of the dynamic stand, for example, reverse for skipping an unused face (picture), showing only the first and second, and also eliminated the one-sided wear of the contacting elements and thereby increase the service life of the stand;

- the implementation of the mechanism of rotation of the prisms with the possibility of reliable and accurate fixation of the prisms by providing a contact spot between the surfaces of the driven sprocket and the drive disk equal to the face area of the driven sprocket, increased stability and clarity of the advertising information image displayed on the dynamic stand;

- supplying the drive disk with a half-disk segment configured to interact with the response groove in the form of a segment based on the driven sprocket, as well as supplying the driven sprocket with a retainer configured to interact with the response element of the drive disk provided reliable fixation from mutual displacement.

The utility model is illustrated by drawings, where:

- figure 1 is a General view of a dynamic stand;

- figure 2-5 - the mechanism of rotation of the prisms.

The dynamic stand (see Fig. 1) contains an information field 1 formed by a series of demonstration elements installed in the housing 2 in the form of equilateral trihedral prisms 3 with components applied to their faces that make up three successive advertising information images, engine 4 drive shaft 5 and prism rotation mechanism. Prisms 3 are mounted vertically on axles 6, rollers 7 with bearings 8, with the possibility of rotation around the axis.

The prism turning mechanism includes mounted on the drive shaft 5, which can be multifaceted, for example, drive disks 9 and driven sprockets 10, rigidly mounted on the rollers 7 of the prisms 3. The drive disks 9 are made with a cylindrical pin 11, a half-disk segment 12 and an annular groove 13 located on the protruding hub of the drive disk 9. In this groove is placed with the possibility of moving along it a centering lock 14 of the driven sprocket 10. The driven sprockets 10 are made in the form of a prism with radial grooves 15 in each of the peaks and the grooves 16 in the base of each face. Mounted driven sprockets 10 with the possibility of interaction of the grooves 15 with the fingers 11. The engagement elements of the drive discs 9 can be placed with sequential angular displacement around the circumference of the location of the finger 11 relative to the finger 11 of the previous drive disc 9.

Dynamic stand works as follows.

When you turn on the engine 4, the drive shaft 5 rotates the drive discs 9. The driven sprocket 10 is in the position of the contact contact of one of its faces with the diametrical plane of the corresponding drive disc 9 (see figure 2). During rotation, the drive disk 9 approaches with its cylindrical finger 11 to the radial groove 15 of the driven sprocket 10, abuts with the finger 11 against the edge of the groove 15, acts on it by turning the driven sprocket 10 (see figure 3). During the rotation, the groove 15 engages with the finger 11, moves (slides) along its working surface until it is rotated through an angle of 120 degrees. At the end of the turn, the finger 11 disengages from the groove 15 and the driven sprocket 10 is set

in the position of the contact contact with the diametrical plane of the drive disk 9 (see figure 4). With further rotation of the drive disk 9, the half-disk element 12 enters an additional reference contact with the groove 16 (see Fig. 5), which ensures the fixation of the position of the prism 3 and the image on it during the demonstration of information. Further rotation of the drive shaft 5 and the drive disks 9 repeats the cycle, changes the image on the information field 1. When the drive drive 9 rotates, the centering latch 14 slides along the groove 13, which with its walls holds it and the driven sprocket 10 from displacement. When reverse is turned on, the rotation of the above structural elements is carried out in the opposite direction.

Thus, this useful model solved the task of increasing the stability and clarity of the advertising information image displayed on the dynamic stand over the entire life of the device, increasing the reliability and expanding the functionality of the stand.

Claims (6)

1. A dynamic stand containing mounted on the supports with the possibility of rotation around the prism’s own axis with components printed on the face, comprising a changing advertising and information image, an engine, a drive shaft and a prism turning mechanism, including driving disks mounted on the drive shaft, kinematically connected with the driven sprockets rigidly fixed on the axes of the prisms, characterized in that the drive disks are equipped with engagement elements in the form of a finger, driven sprockets are made in the form of trihedral prisms, each of the vertices are formed by radial grooves, the driven sprockets are mounted to cooperate with said slots engagement elements leading discs. 2. The stand according to claim 1, characterized in that the prism rotation mechanism is configured to allow reverse rotation by performing each of the rays of the driven sprockets symmetrical with respect to the radial groove at its apex with the possibility of two-sided rotation. 3. The stand according to claim 1, characterized in that the mechanism of rotation of the prisms is made with the possibility of reliable and accurate fixation of the prisms by providing a contact spot of the surfaces of the driven sprocket and the drive disk equal to the face area of the driven sprocket. 4. The stand according to claim 1, characterized in that the leading disk is equipped with a half-disk segment, configured to interact with the return groove in the form of a segment based on the driven sprocket, providing additional fixation from mutual displacement. 5. The stand according to claim 1, characterized in that the engagement elements of the driving disks are placed with sequential angular displacement around the circumference of the finger relative to the finger of the previous disk. 6. The stand according to claim 1, characterized in that the driven sprocket is provided with a latch made with the possibility of interaction with the response element of the leading disk.