JP2009195332A - Display shelf and display shelf system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To change the height position of a mounting board of a display shelf for displaying a projector-projected image on one screen projected from a projector from the rear side to the front side of a plurality of stages of transmissive type screens disposed in association with a plurality of stages of mounting boards on which articles can be mounted. <P>SOLUTION: A plurality of mounting boards 102 (102b and 102c) on which articles can be mounted are attached to the front face of a base body 103 in such a way as the height position can be changed, and a plurality of projection mirrors 110 (110b and 110c) are integrally connected to the mounting boards 102 (102b and 102c). The projection mirrors 110 reflect a plurality of unoverlapping parts of the projector-projected image on one screen projected by the projector, and project the respective reflected images to the rear side of the screens 106 (106b and 106c) respectively. The height position of the projection mirrors 110 (110b and 110c) as well as the height position of the mounting boards 102 (102b and 102c) can be changed. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a shelf suitable for display of items, and a display shelf and a display shelf system capable of transmitting and projecting information about items to be displayed using a projector.

  Display shelves for displaying items are typically widely used in retail stores, for example, supermarkets, convenience stores, home centers, department stores and the like. In a retail store, merchandise is displayed on a display shelf, and a shelf label is attached in association with the merchandise to be displayed. The shelf label is intended to show the customer the price of the associated product and other information. In recent years, electronic shelf labels have been developed as such shelf labels (see Patent Document 1). The electronic shelf label is formed of, for example, a liquid crystal panel, an organic EL panel, or the like (see, for example, paragraph 0008 of Patent Document 1).

  Display shelves used in retail stores mainly display products and display the price and other information of products displayed using shelf labels and electronic shelf labels. On the other hand, a technique called POP advertisement (Point of Purchase) has been widely used as a technique for paying attention to products displayed on display shelves and leading to more purchases. Patent Document 2 discloses a display shelf (showcase in Patent Document 2) in which a projector and a screen for transmitting and projecting a projection image from the projector are provided on the ceiling wall of the display shelf. By adopting such technology, the display of products displayed on display shelves using projector projection images that are normally projected onto the screen without attaching POP advertisements printed on recording media such as paper. It is expected to promote the effect (see paragraph 0018 of Patent Document 2).

  In the electronic shelf label shown in Patent Document 1, it is difficult to take a wide information display area. The main reason is that from the viewpoint of price, but another reason is that it is difficult to take a wide information display area from the viewpoint of the yield of liquid crystal panels and organic EL panels. Patent Document 1 discloses that a plurality of thin display devices are connected horizontally to form a horizontally long shape (see FIG. 8). In this case, a seam is inevitably formed between the thin display devices. Will occur. For this reason, natural and beautiful display cannot be performed at the joint portion.

  In addition, because the information display area cannot be widened with an electronic shelf label, the information that can be displayed there is limited to the price of the corresponding product and other information. For this reason, it is difficult to give an electronic shelf label a function like a POP advertisement.

  For this reason, a plurality of stages of transmissive screens are provided in association with a plurality of stages of mounts on which articles can be placed, and projected from the back side of the transmissive screen by the projector. A display shelf has been devised to display a one-screen projector projection image (see Patent Document 3). Such display shelves project the projected image from the projector through the screen in that the projected image projected by the projector is projected from the back onto a multi-stage screen associated with the multi-stage mounting table. It is different from the display shelf (showcase in Patent Document 2) described in Patent Document 2 that only stays in projection.

JP 2005-099888 A JP 2001-245756 A JP 2007-289636 A

  In a display shelf for displaying commodities, it is desirable that the height position of the mounting table can be varied according to the size of the commodities to be displayed, especially the height dimension. Therefore, it is desired to develop a technique that allows the height position of the mounting table to be freely changed even in the display shelf described in Patent Document 3.

  Further, in the display shelf described in Patent Document 3, it is important to correctly align the projector projection image of one screen projected from the projector with respect to a structure of a plurality of stages of transmissive screens. Such alignment is highly difficult in consideration of individual differences in display shelves and changes over time.

  An object of the present invention is to provide a one-screen projector projection image projected by a projector from the rear surface side of a front surface side of a plurality of transmissive screens arranged in association with a plurality of mounting tables on which goods can be placed. On the premise of the structure to be displayed, the height position of the mounting table is made variable.

  Another object of the present invention is to provide a one-screen projector projection that is projected by a projector from the back side to the front side of a plurality of transmissive screens arranged in association with a plurality of stages on which a product can be placed. On the premise of a structure for displaying an image, a projector projected image of one screen projected from a projector can be correctly aligned with a structure called a multi-stage transmissive screen.

  The display shelf of the present invention includes a base that forms a first space therein and a second space that is disposed in front of the base and extends in the horizontal direction and communicates with the first space. , An article can be placed on the upper surface, and at least one stage is mounted on a plurality of stages, the height position of which is variably attached to the base body, and is positioned in a front area of each of the above-described places, In order to arrange a plurality of transmissive screens capable of transmissively projecting a projector projection image projected from the back surface side, which is the second space side, on the front surface side, and a projector that projects the projector projection image, the first or the second A plurality of non-overlapping parts of a projector projection image of one screen projected by the projector installation unit provided in a lower position of the space 2 and the projector guided upward in the first space. A plurality of projection mirrors that individually reflect the light toward the second space and project it on the back side of the screen; A connection structure that integrally connects the projection mirror that projects the projector projection image toward the screen provided on the mounting table, and the projection mirror also has a variable height position together with the mounting table; Is provided.

  The display shelf system of the present invention includes the display shelf and a projector image transmission device that transmits image data to the projector, and the projector image transmission device performs data transmission to the projector. A transmission unit, and a data transmission process in which display data corresponding to each of the screens are independently set and the image data of the projector image that forms the basis of the projector projection image is transmitted to the projector by the data transmission unit; And a data correction process for independently changing the display position of the display area in the projector image.

  A display shelf system according to another aspect of the present invention includes the display shelf and a projector image transmission device that transmits image data to the projector, the projector image transmission device being connected to the projector. A data transmission unit that executes data transmission and a display area corresponding to each of the screens are independently set, and image data of a projector image that forms the basis of the projector projection image is transmitted to the projector by the data transmission unit. A control unit that executes data transmission processing and data correction processing that independently changes the display size of the display area in the projector image.

  According to the present invention, at least one mounting table is attached to the base so that the height position can be changed, and the mounting position is provided on the mounting table. Since the connection structure that integrally connects the projection mirror that projects the projector projection image toward the screen is also capable of changing the height position of the projection mirror together with the mounting table, the size of the product to be displayed, especially The height position of the mounting table can be freely changed according to the height dimension. In addition, according to the present invention, since the display position and display size of the display area in the projector image can be changed independently, a one-screen projector that projects from a projector to a plurality of transmissive screens. Projection images can be correctly aligned, and projector projection images can be displayed on the screens of individual display shelves without positional deviation.

  An embodiment of the present invention will be described with reference to FIGS. This embodiment introduces a display shelf system 11 suitable for application to a supermarket.

  FIG. 1 is a perspective view of a display shelf 101 constituting the display shelf system 11. The display shelf system 11 according to the present embodiment includes a display shelf 101 installed in a store, a projector 201 (see FIGS. 2 and 15) built in the display shelf 101, and a display shelf 101 similar to the projector 201. It is composed of a computer 301 (see FIGS. 2 and 15) as a built-in projector image transmission device.

  The display shelf 101 has a mounting table 102 on which a product A, which is a product, can be placed and displayed. The mounting table 102 is provided in three stages. Here, for convenience, they are referred to as mounting tables 102a, 102b, and 102c from the bottom. These mounting tables 102 (mounting tables 102a, 102b, and 102c) have three mounting table bases 104 having a rectangular parallelepiped shape with a hollow inside on a front surface of a rectangular parallelepiped base body 103 that is tall and hollow inside. By being fixed, it is formed on the upper surface of the mounting base 104. That is, the upper surface of the mounting table base 104 is formed in a flat plate shape so as to function as the mounting table 102 on which the product A can be mounted. Of the mounting table bases 104, the mounting table base 104a positioned at the bottom is formed with the largest height, and the two-stage mounting table bases 104b and 104c positioned above the mounting table base 104a are substantially the same height. It is formed with a size. These two stages of mounting table bases 104b and 104c are attached to the base 103 so that their height positions can be varied. Its structure will be described later.

  A top plate 105 is fixed to the base 103 so as to be positioned above the mounting table 102c located at the highest position. Similarly to the mounting table 102, the top plate 105 is also formed of a rectangular parallelepiped member having a hollow inside. As an example, the base 103, the mounting base 104, and the top plate 105 that form the display shelf 101 are formed by attaching a sheet metal member to a frame made of a metal frame (not shown).

  Next, a screen 106 is attached to the front surface of the mounting table base 104 and the top plate 105. Here, for convenience, among the screens 106, the screen 106a is provided on the mounting base 104a, the screen 106b is provided on the mounting base 104b, and the screen 106c is provided on the mounting base 104c. What is provided in the top plate portion 105 is referred to as a screen 106d. These screens 106 (screens 106 a, 106 b, 106 c, 106 d) all have a horizontally long shape that is seamlessly formed across the width of the mounting table base 104 (the mounting table bases 104 a, 104 b, 104 c) and the top plate 105. Is formed. These screens 106 (screens 106a, 106b, 106c, 106d) have a frosted glass-like structure, for example, and are of a transmissive type capable of transmitting and projecting a projector projection image projected from the back side onto the front side.

  FIG. 2 is an overall vertical side view showing the display shelf 101, the projector 201, and the computer 301 (projector image transmission device) constituting the display shelf system 11 together with the internal structure of the display shelf 101. As apparent from FIG. 2, the base 103, the individual mounting base portions 104 (mounting base portions 104 a, 104 b, 104 c), and the top plate portion 105 communicate with each other inside. Here, for convenience, the cavity formed inside the base body 103 is referred to as a first space FS, and the cavity formed inside the mounting table base 104 (104a, 104b, 104c) and the top plate 105 is a second. This space SS will be called. The second space SS communicates with the space of the first space FS on the front surface side of the base 103 and extends in the horizontal direction.

  The display shelf 101 uses such an internal space (the first space FS and the second space SS), and projector projection images projected from the lens 202 by the projector 201 are displayed on the individual screens 106 (screens 106a, 106b, 106c, 106d). That is, the projector 201 is a liquid crystal projector as an example, receives the image data of the projector image transmitted from the computer 301, generates a projector projection image based on the received image data, and projects it from the lens 202. Such a projector 201 is installed in the projector installation unit 107a provided in the second space SS inside the mounting base 104a located at the lowest position, and the projector is projected toward the rear in the display shelf 101. An image can be projected. Further, in the second space SS inside the mounting table base 104a, a computer mounting unit 107b is provided above the projector installation unit 107a. A computer 301 is mounted on the computer mounting portion 107b. As shown in FIG. 2, as a computer 301, a desktop type arranged horizontally is used as an example. As another example, a notebook computer may be used as the computer 301.

  In the internal space (the first space FS and the second space SS) of the display shelf 101, the projector projection images projected from the projector 201 are directed toward the back of the individual screens 106 (screens 106a, 106b, 106c, 106d). An optical system 108 is provided. The optical system 108 first receives the projector projection image projected from the projector 201 and reflects it upward, and the projector projection image reflected by the reflection mirror 109 on each screen 106 (106a, 106b). , 106c, 106d), and four projection mirrors 110 (110a, 110b, 110c, 110d) that reflect toward the base. The individual projection mirrors 110 (110a, 110b, 110c, 110d) are respectively arranged at positions where the optical path lengths from the projector 201 can be substantially matched. However, since a sufficient optical path length cannot be taken from the projector 201 to the screen 106a positioned at the lowermost position, a single folding mirror 111 is disposed between the reflection mirror 109 and the projection mirror 110a, and the optical path length is set. Secured.

  What is important here is that the projector projection image projected from the lens 202 by the projector 201 is an image of one screen configuration. The projector projection image having such a single screen configuration is divided by four projection mirrors 110 (110a, 110b, 110c, 110d) and guided to individual screens 106 (106a, 106b, 106c, 106d).

  FIG. 3 is an exploded perspective view of the display shelf 101. The base 103 of the display shelf 101 is a gauge structure formed by four pillars 112 standing at four corners and a plurality of joints 113 that connect the lower and upper ends of the four pillars 112. Eggplant. The plurality of connecting bodies 113 are connected to each other to form a pair of upper and lower rectangular shapes, and the upper ends and the lower ends of the four pillar portions 112 are respectively connected and fixed. The column part 112 and the connection body 113 are formed by the elongate metal plate bent to the L-shape as an example.

  A pair of left and right side walls 114 are attached to both sides of the display shelf 101. These side walls 114 are formed by a flat steel plate as an example, and are connected and fixed to two column portions 112 located on both sides and two upper and lower connecting bodies 113 that connect these column portions 112. .

  A bottom plate 115 (see FIG. 4) is attached to the bottom of the display shelf 101. The bottom plate 115 is formed by a flat iron plate as an example, and is connected and fixed to four connecting bodies 113 that are connected to each other in a rectangular shape.

  A top plate 116 is attached to the upper surface of the display shelf 101. The top plate 116 is formed of a flat iron plate as an example, and is connected and fixed to four connecting bodies 113 connected in a rectangular shape located at the top.

  The back surface of the display shelf 101 is reinforced by two upper and lower reinforcing plates 117. These reinforcing plates 117 are formed by an elongate flat plate-like iron plate as an example, and are stretched over and fixed to the two left and right column portions 112 located on the back side.

  Thus, the base body 103 maintains a strong structural strength by connecting and fixing the wall structures of the side wall 114, the bottom plate 115, and the top plate 116 to the gauge structures of the column portion 112, the connection body 113, and the reinforcing plate 117. ing.

  As shown in FIG. 3, a mounting base 104 a is fixed to the lower front surface of the base 103, and a top plate 105 is fixed to the upper front of the base 103. The two-stage mounting base portions 104b and 104c disposed between the mounting base portion 104a and the top plate portion 105 are higher than the pair of left and right column portions 112 positioned on the front surface side constituting the base body 103. It is attached freely. What is important here is that among the four projection mirrors 110 (110a, 110b, 110c, 110d), the second-stage projection mirror 110b from the bottom corresponding to the second-stage mounting base 104b is the bottom. The projector projection image is projected toward the screen 106b of the mounting base 104b. Therefore, the second stage mounting base 104b from the bottom and the second stage projection mirror 110b from the bottom are associated with each other. The projection mirror 110c in the third stage from the bottom associated with the third stage mounting base 104c from the bottom projects the projector projection image onto the screen 106c of the mounting base 104c. Therefore, the third stage mounting base 104c from the bottom and the third stage projection mirror 110c from the bottom are associated with each other. The second-stage mounting base 104b from the bottom and the second-stage projection mirror 110b, which are associated with each other in this way, are integrally connected by a pair of left and right connecting arms 118 that form a connecting structure, and both have a height. It is adjustable. Similarly, the third-stage mounting base 104c and the third-stage projection mirror 110c, which are associated with each other, are integrally connected by a pair of left and right connection arms 118 that form a connection structure. Adjustable height.

  As shown in FIG. 3, the base 103 has an open front surface between the lowermost stage mounting base 104 a and the top plate 105. Since the two-stage mounting base portions 104b and 104c are attached to the opening portions so as to be adjustable in height, the opening portions are closed at the mounting base portions 104b and 104c. On the other hand, the part between the bottom stage mounting base 104a and the second stage mounting base 104b, the part between the second stage mounting base 104b and the third stage base 104c, And an opening part remains in the part between the mounting base part 104c and the top-plate part 105 of a 3rd step. Therefore, the base 103 has a structure in which three decorative panels 119 can be attached and detached at these three locations so as to block the opening. These decorative panels 119 are prepared in various widths depending on the height of the opening portion, and those having the optimal width can be selected and mounted on the base 103.

  Further, a back panel 120 is detachably attached to the back surface of the base 103 (see also FIGS. 1 and 2). The back panel 120 is divided into two upper and lower parts, and is formed of a flat iron plate as an example.

  Further, a front panel 121 is detachably attached to the front surface of the lowermost stage mounting base 104a (see also FIGS. 1 and 2). As an example, the front panel 121 is formed of a flat iron plate.

  FIG. 4 is a rear view of the base 103 of the display shelf 101. In the pair of left and right pillars 112 constituting the back side of the base 103, back mounting holes 122 are formed at positions corresponding to the four corners of the two back panels 120. As shown in FIG. 3, the back panel hooks 123 are formed at the four corners of the two back panels 120 at positions corresponding to the back mounting holes 122 and can be hooked into the back mounting holes 122. Is provided. Therefore, the two back panels 120 can be detachably attached to the back surface of the base body 103 by hooking the back panel hooks 123 into the back surface mounting holes 122.

  FIG. 5 is a perspective view showing an attaching / detaching structure for attaching the mounting table 102 (mounting tables 102b and 102c) to the base 103 so that the height thereof can be adjusted. As the attachment / detachment structure, a plurality of front mounting holes 124 are arranged in a row in the height direction in the pair of left and right pillars 112 constituting the front side of the base body 103. And the mounting base hook 125 of the shape which can be hooked in the front mounting hole 124 is provided in the back side both sides of the mounting base base parts 104b and 104c which comprise the mounting bases 102b and 102c. The mounting base hook 125 has a double structure that can be hooked to two front mounting holes 124 adjacent vertically. When the mounting table hook 125 is hooked in the front mounting hole 124, the back surface of the mounting table bases 104 b and 104 c comes into contact with the column part 112. Thereby, the mounting bases 104b and 104c whose front side tends to fall downward due to their own weight are supported by the column part 112, and the mounting base 102b is securely attached to the base body 103 together with the corresponding projection mirrors 110b and 110c. In this case, the arrangement pitch of the front mounting holes 124 defines the minimum pitch that enables the height adjustment of the mounting tables 102b and 102c.

  As shown in FIG. 3, the front mounting hole 124 formed in the column part 112 also contributes to the mounting of the decorative panel 119. In other words, the decorative panel hooks 126 having the same shape as the mounting table hooks 125 provided on the both sides on the back side of the mounting table base 104b (104c) are provided on both sides on the back side of the decorative panel 119. ing. Therefore, the three decorative panels 119 can be detachably attached to the front surface of the base 103 by hooking the decorative panel hook 126 on the front mounting hole 124.

  Here, another example of a detachable structure for attaching the mounting table 102 (mounting tables 102b and 102c) to the base body 103 so as to be adjustable in height will be described with reference to FIGS.

  FIG. 6 is a perspective view showing the attachment / detachment structure. In this example, stopper pins 127 whose heights are adjustable are provided on the four pillars 112 so as to extend to the first space FS side which is the internal space of the base 103. Then, by holding the pair of left and right connecting arms 118 that integrally connect and fix the second and third stage mounting bases 104 b and 104 c and the projection mirrors 110 b and 110 c so as to be sandwiched between the stopper pins 127. The mounting bases 104b and 104c and the projection mirrors 110b and 110c can be fixed at arbitrary positions. This structure is shown in FIG.

  7A is a side view of the mounting table 102 (mounting tables 102b and 102c) showing a state before the position is restricted by the stopper pin 127, and FIG. 7B is a state where the position is restricted by the stopper pin 127. 2 is a side view of the mounting table 102 (mounting tables 102b and 102c). The connecting arm 118 is supported by a stopper pin 127 attached to a column part 112 positioned on the front side at the lower end on the front side, and a stopper pin 127 attached to the column part 112 located on the rear side on the rear side. It is supported by. Thus, the front and rear sides of the pair of left and right connecting arms 118 that integrally connect and fix the second and third stage mounting bases 104b and 104c and the projection mirrors 110b and 110c are a pair of front and rear stopper pins. 127, the mounting bases 104b and 104c and the projection mirrors 110b and 110c can be fixed in position.

  At this time, the stopper pin 127 is attached to the column part 112 so that the height can be adjusted. Therefore, by setting the height of the pair of stopper pins 127 attached to the front and rear pillars 112 to be appropriately set (see FIG. 7A), the mounting bases 104b and 104c and The projection mirrors 110b and 110c can be fixed at desired height positions (see FIG. 7B).

  A semicircular fitting groove 128 into which the stopper pin 127 is fitted is formed at the front lower end of the connecting arm 118. By fitting the stopper pin 127 into such a fitting groove 128, the positional deviation in the front-rear direction of the mounting bases 104b and 104c and the projection mirrors 110b and 110c is suppressed, and the mounting bases 104b and 104c and the projection It is possible to reliably fix the positions of the mirrors 110b and 110c.

  FIG. 8 is a perspective view showing the height adjustment structure of the stopper pin 127. In this example, the column part 112 has a double structure. That is, the column base 112a which is a pipe-like member having a square cross section is provided, and the surrounding member 112b covers the periphery thereof. The surrounding member 112b does not completely cover the entire circumference of the column base 112a, and a slit 112c is formed at a position where the column base 112a is not covered. In the portion where the slit 112c is formed, a gap is formed between the column base 112a and the surrounding member 112b, and a pair of spacers 112d is press-fitted into the gap. A gap communicating with the slit 112c is left at a position where these spacers 112d face each other, and this gap serves as a mover moving space 112e formed along the slit 112c. Thus, the column portion 112 is formed.

  The stopper pin 127 is attached to the column part 112 so as to be adjustable in height by using a slit 112c formed in the column part 112 and a mover moving space 112e. That is, the rectangular parallelepiped movable element 129 is slidably fitted in the movable element moving space 112e. The moving element 129 has a screw hole 129a formed at a position exposed from the slit 112c regardless of the slide movement position, and the screw 127a formed on the stopper pin 127 is screwed into the screw hole 129a. ing. Therefore, by rotating the stopper pin 127 clockwise, the screw 127a of the stopper pin 127 is tightened with respect to the screw hole 129a of the moving element 129, and the surrounding member 112b is interposed between the stopper pin 127 and the moving element 129. Thus, the stopper pin 127 is fixed at that position. In order to adjust the height of the stopper pin 127, the stopper pin 127 may be rotated counterclockwise to release the outer member 112b between the stopper pin 127 and the mover 129. Thereby, the stopper pin 127 can be moved along the slit 112c. Therefore, if the stopper pin 127 is rotated clockwise again at a desired position, the stopper pin 127 is fixed at that position.

  As described above, in the example shown in FIGS. 6 to 8, the mounting table 102 (mounting table) is used as an attaching / detaching structure for mounting the mounting table 102 (mounting tables 102 b and 102 c) to the base 103 so that the height can be adjusted. 102b, 102c) can be adjusted steplessly.

  FIG. 9 is an exploded perspective view showing the reflection mirror adjustment mechanism 130 for adjusting the angle of the reflection mirror 109. The reflection mirror 109 is fixed in a surface contact state to a metal reflection mirror holding plate 131 having a U-shaped cross section by a technique such as adhesion. A reflection mirror holding plate 131 that holds the reflection mirror 109 is attached to a metal reflection mirror support column 132 that is a pipe-shaped member having a square cross section that is fixed at both ends to both sides of the base body 103 so that the angle can be adjusted. . The angle adjustment structure will be described with reference to FIG.

  FIG. 10 is an exploded side view showing the reflecting mirror adjusting mechanism 130 in an exploded manner. An angle adjusting plate 133 having elasticity is welded to the back side of the reflection mirror holding plate 131. The angle adjusting plate 133 is arranged such that the portions other than the welded portion are slightly separated from the reflection mirror holding plate 131. The angle adjusting plate 133 has a pair of fixing screw holes 134 positioned in the vicinity of the welded portion with respect to the reflection mirror holding plate 131 and one piece positioned farther from the welded portion than these fixing screw holes 134. The adjustment screw hole 135 is formed.

  Then, the two fixing screws 137 inserted through the two large and small insertion holes 136a and 136b formed in the reflection mirror support pillar 132 are screwed into the fixing screw hole 134 and tightened, whereby the reflection mirror support pillar 132 is inserted. The reflection mirror holding plate 131 is fixed to the surface. In this case, the reflection mirror support column 132 is inclined and attached to the base 103, and the reflection mirror holding plate 131 is fixed to the upward surface of the base 103, so that it is held by the reflection mirror holding plate 131. The reflecting mirror 109 is also mounted in an upward state.

  An adjustment screw 138 is screwed into and tightened in the adjustment screw hole 135 formed in the angle adjustment plate 133, and a contact portion 139 at the tip of the adjustment screw 138 contacts the back surface of the reflection mirror holding plate 131. ing. Thereby, by tightening or loosening the adjusting screw 138, the angle of the reflecting mirror holding plate 131 with respect to the angle adjusting plate 133 is slightly changed, and the angle of the reflecting mirror 109 held by the reflecting mirror holding plate 131 is changed. Adjustment is possible.

  FIG. 11 is a side view of the reflection mirror adjustment mechanism 130 for explaining the angle adjustment operation of the reflection mirror 109. When the adjustment screw 138 is rotated in the clockwise direction, the adjustment screw 138 is tightened, and the contact portion 139 presses the back surface of the reflection mirror holding plate 131. As a result, the angle adjustment plate 133 is bent by its own elasticity, and the reflection mirror 109 held on the reflection mirror holding plate 131 is inclined in a direction to increase the upward angle. On the other hand, when the adjusting screw 138 is rotated counterclockwise, the adjusting screw 138 is loosened. As a result, the angle adjustment plate 133 returns to the restoring direction by its own elasticity, and the reflection mirror 109 held by the reflection mirror holding plate 131 is inclined in a direction that reduces the upward angle. Thus, the angle of the reflection mirror 109 can be adjusted by rotating the adjusting screw 138 clockwise and counterclockwise.

  FIG. 12 is an exploded perspective view showing the projection mirror adjusting mechanism 140 for adjusting the angle of the projection mirror 110 (110a, 110b, 110c, 110d). The projection mirror 110 (110a, 110b, 110c, 110d) is fixed in a surface contact state to a metal projection mirror holding plate 141 having a U-shaped cross section by a technique such as adhesion. The projection mirror holding plate 141 that holds the projection mirror 110 (110a, 110b, 110c, 110d) is attached to a metal projection mirror support column 142 that is a pipe-shaped member having a square cross section so that the angle can be adjusted. Here, the projection mirror support column 142 shown in FIG. 12 is for the projection mirrors 110b and 110c corresponding to the mounting tables 102b and 102c whose height can be adjusted, and both ends thereof are mounted on the mounting table base. 104b and 104c and the projection mirrors 110b and 110c are fixed to a pair of connecting arms 118 that form a connecting structure for integrally connecting them. On the other hand, the projection mirror support pillars 142 for the projection mirrors 110 a and 110 d corresponding to the mounting table 102 a and the top plate part 105 whose height cannot be adjusted are fixed to both side parts of the base 103. Hereinafter, the angle adjustment structure of the projection mirror 110 (110a, 110b, 110c, 110d) will be described with reference to FIG.

  FIG. 13 is an exploded side view showing the projection mirror adjusting mechanism 140 in an exploded manner. An angle adjusting plate 143 having elasticity is welded to the rear surface side of the projection mirror holding plate 141. The angle adjusting plate 143 is arranged such that the portions other than the welded portion are slightly separated from the projection mirror holding plate 141. The angle adjusting plate 143 includes a pair of fixing screw holes 144 positioned in the vicinity of the welded portion with respect to the projection mirror holding plate 141, and one piece positioned farther from the welded portion than these fixing screw holes 144. The adjustment screw hole 145 is formed.

  Then, the two fixing screws 147 inserted through the two large and small insertion holes 146a and 146b formed in the projection mirror support column 142 are screwed into the fixing screw hole 144 and tightened, thereby the projection mirror support column 142. The projection mirror holding plate 141 is fixed to the head. In this case, the projection mirror support column 142 is inclined and attached to the base body 103, and the projection mirror holding plate 141 is fixed to the downward surface of the base body 103, so that it is held by the projection mirror holding plate 141. The projection mirrors 110 (110a, 110b, 110c, 110d) are also attached in a downwardly upward state.

  An adjustment screw 148 is screwed into and tightened in the adjustment screw hole 145 formed in the angle adjustment plate 143, and a contact portion 149 at the tip of the adjustment screw 148 contacts the back surface of the projection mirror holding plate 141. ing. Thereby, by tightening or loosening the adjusting screw 148, the angle of the projection mirror holding plate 141 with respect to the angle adjusting plate 143 changes slightly, and the projection mirror 110 (110a, 110b, 110c, 110d) can be adjusted.

  FIG. 14 is a side view of the projection mirror adjustment mechanism 140 for explaining the angle adjustment work of the projection mirror 110 (110a, 110b, 110c, 110d). When the adjustment screw 148 is rotated in the clockwise direction, the adjustment screw 148 is tightened, and the contact portion 149 pushes the back surface of the projection mirror holding plate 141. As a result, the angle adjusting plate 143 is bent by its own elasticity, and the projection mirror 110 (110a, 110b, 110c, 110d) held by the projection mirror holding plate 141 is inclined in a direction to decrease the downward angle. On the other hand, when the adjusting screw 148 is rotated counterclockwise, the adjusting screw 148 is loosened. As a result, the angle adjustment plate 143 returns to the restoring direction by its own elasticity, and the projection mirror 110 (110a, 110b, 110c, 110d) held by the projection mirror holding plate 141 is inclined in a direction to increase its downward angle. To do. Thus, the angle of the projection mirror 110 (110a, 110b, 110c, 110d) can be adjusted by rotating the adjusting screw 148 clockwise and counterclockwise.

  FIG. 15 is a block diagram illustrating a hardware configuration of a computer 301 that transmits image data to the projector 201. In the base 103, the computer 301 mounted on the computer mounting portion 107b is only the main body 302 (see FIGS. 2 and 4). In order to make the computer 301 function, it is necessary to connect a display 303, a keyboard 304, and a pointing device 305 such as a mouse or a touch pad to the main body 302. In order to connect the display 303, the keyboard 304, and the pointing device 305 to the main body 302, the front panel 121 is opened, the main body 302 is taken out and exposed to the outside. As another example, if the computer 301 placed on the computer placement unit 107b and accommodated in the base 103 is a notebook computer, a display 303, a keyboard 304, and a pointing device 305 are connected to the main body 302 in advance. It has become.

  Such a computer 301 has a microcomputer 306 as a control unit. The microcomputer 306 is mainly configured by a CPU 307 that executes various arithmetic processes, and a ROM 308 that fixedly stores fixed data such as BIOS and a variety of variable data are rewritably stored in the CPU 307 and used as a work area. The RAM 309 is connected via a bus line 310. An HDD 311 and a CD-ROM drive 312 are connected to such a microcomputer 306. As an example, a CD-ROM 313 to a CD-ROM drive 312 storing an OS (operating system, see FIG. 16) and various application programs are stored. Can read the information and install it in the HDD 311.

  The display 303, the keyboard 304, and the pointing device 305 are also connected to the microcomputer 306. The display 303 is an output device for the microcomputer 306, and the keyboard 304 and the pointing device 305 are input devices for the microcomputer 306.

  Further, a communication interface 314 as a data transmission unit is connected to the microcomputer 306. The communication interface 314 is for performing data communication with the projector 201 via the communication line 401, and USB is used as an example. The communication interface 314 needs to support a protocol that enables communication with the projector 201.

  FIG. 16 is a schematic diagram exemplifying a mechanism on the computer 301 for editing and generating image data of a projector image serving as a basis of a projector projection image projected by the projector 201 and causing the projector 201 to project the image data. The computer 301 enables editing and generation of such image data. As a mechanism for this, the computer 301 has installed image forming projection software 351 as an application program installed in the HDD 311. An image library 352 used together with the image forming projection software 351 is also installed in the HDD 311. Further, the display position of a display area IMGA (see FIGS. 17, 20, etc.) to be described later in the projector image is displayed. A display reference file 353 and a display correction file 354 for setting a display position definition to be specified are also installed in the HDD 311.

  The image forming projection software 351 according to the present embodiment is programmed so that image data can be edited and generated on the computer 301, and characters can be superimposed on the generated image data. In addition, the image forming projection software 351 uses various model images included in the image library 352 when editing and generating image data, and is programmed so that these can be pasted on the edited and generated images. Has been. The image library 352 stores photographic data and pattern data of various foods as model images. In addition, the image library 352 also stores a projector image for adjusting the angle of the reflection mirror 109.

  FIG. 17 is a schematic diagram illustrating an example of a projector image that is edited and generated on the computer 301 that is the basis of the projector projection image that the projector 201 projects. As described above with reference to FIG. 2, the projector projection image having a single screen configuration projected from the lens 202 by the projector 201 is divided by the four projection mirrors 110 (110 a, 110 b, 110 c, and 110 d) and is divided into individual screens 106. The images are configured so as to be guided to (106a, 106b, 106c, 106d). Thus, a single-screen projector image that is the basis of a projector projection image that can be edited and generated by the image forming projection software 351 is aligned with each screen 106 (106a, 106b, 106c, 106d) and formed in a band shape. A desired image is edited and generated in the display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4). In the projector image, areas other than the display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) are blacked out.

  Here, in the present embodiment, display positions and display sizes are individually set for individual display areas IMGA (IMGA1, IMGA2, IMGA3, and IMGA4) in the projector image that can be edited and generated by the computer 301. . Data for determining the display position and display size of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) is a display reference file 353 and a display correction file 354 installed in the HDD 311 shown in FIG.

  When the image forming projection software 351 is started, all or part of the program code is copied to the RAM 309 together with the display reference file 353 and the display correction file 354, and the processing speed based on the image forming projection software 351 is increased. . Further, along with the copying of the image forming projection software 351 to the RAM 309, all or part of the image library 352 is also copied to the RAM 309, so that the processing speed can be increased. The microcomputer 306 can transmit the image data edited and generated by the image forming projection software 351 from the communication interface 314 to the projector 201 via the communication line 401.

  FIG. 18 is a flowchart for explaining the switching process between the edit mode, the projection mode, and the correction mode, which is executed by the computer 301 according to the program described in the image forming projection software 351. When the image forming projection software 351 is activated, it can be switched between a projection mode, an edit mode, and a correction mode. For mode switching, for example, an operation instruction is given by the keyboard 304 and the pointing device 305.

  When the editing mode is selected and designated (Y in step S101), editing processing is possible (step S102). In the editing process in step S102, the CPU 307 displays the projector image shown in FIG. 17 on the display 303, and displays individual display areas IMGA (IMGA1, IMGA2, IMGA3) corresponding to the individual screens 106 (106a, 106b, 106c, 106d). , IMGA4) is allowed to superimpose a desired image.

  When the projection mode is selected and designated (Y in step S103), projection is possible (step S104). In the projection process of step S104, the CPU 307 executes a data transmission process of transmitting the image data edited and generated by the editing process of step S102 to the projector 201 via the communication interface 314. Thereby, the projector 201 receives the image data of the projector projection image as illustrated in FIG. 17 and projects a projector projection image based on the image data. As a result, an image edited and generated in each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the image data of the projector image is formed on the back surface of each screen 106 (106a, 106b, 106c, 106d). It is guided to 108 and projected, and the image is displayed on the surface side of each screen 106 (106a, 106b, 106c, 106d).

  When the correction mode is selected and designated (Y in step S105), correction processing is possible (step S106). In this correction process, the angle adjustment process of the reflection mirror 109 and the process of adjusting the display position and display size of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the image data of the projector image are executed. Is possible. Hereinafter, the correction work of each part of the display shelf 101 including these two correction processes will be described.

In the display shelf 101 of the present embodiment, the angle shift of the reflection mirror 109 causes a large position shift of the projector projection image with respect to the individual screens 106 (106a, 106b, 106c, 106d). It must be set correctly. The same applies to the projection mirror 110 (110a, 110b, 110c, 110d). However, since the display shelf 101 is a considerably large device,
Individual differences are likely to occur, and distortion of the substrate 103 depending on the smoothness of the installation location, distortion of the substrate 103 due to secular change, and the like are also likely to occur. Therefore, in the display shelf 101 of the present embodiment, the angle of the reflection mirror 109 can be adjusted by the reflection mirror adjustment mechanism 130, and the projection mirror 110 (110a, 110b, 110c, 110d) of the projection mirror adjustment mechanism 140 can be adjusted. Angle adjustment can be performed. Therefore, for example, when the display shelf 101 is installed in a store or the like, it is desirable to adjust the angles of the reflection mirror 109 and the projection mirror 110 (110a, 110b, 110c, 110d). Among such angle adjustment processes, regarding the angle adjustment of the reflection mirror 109, the display shelf system 11 of the present embodiment performs the angle adjustment process of the reflection mirror 109 as a software process in step S106 shown in FIG. Supported.

  FIG. 19 is a schematic diagram for explaining a method of adjusting the angle of the reflection mirror 109. When execution of the angle adjustment processing of the reflection mirror 109 is designated in step S106 shown in FIG. 18, the image forming projection software 351 calls the projector image for angle adjustment of the reflection mirror 109 from the image library 352, and transmits the communication line. It transmits to the projector 201 via 401. Thus, the projector 201 projects a projector projection image based on the image data of the projector image for adjusting the angle of the reflection mirror 109 from the lens 202. In this way, the projected image projected by the projector 201 includes a landmark image 251. This mark image 251 is included in a region reaching the ceiling surface 150 on the back side of the top plate 116 of the base 103 in the projector projection image of one screen (see FIG. 2). If the angle of the reflection mirror 109 is set correctly, the mark image 251 included in the projector projection image for adjusting the angle of the reflection mirror 109 projected by the projector 201 overlaps the ceiling surface 150. A target 151 for alignment is marked at the expected position (see FIG. 2). The target 151 is formed by, for example, a mark by printing or the like, an uneven shape, or the like. Therefore, if the mark image 251 in the projector projection image projected by the projector 201 overlaps the target 151 formed on the ceiling surface 150, it can be understood that the reflection mirror 109 is set at the correct angle.

  On the other hand, as shown in FIG. 19A, the mark image 251 in the projector projection image is displaced in the front direction of the display shelf 101 with respect to the alignment target 151 formed on the ceiling surface 150. In this case, the angle of the reflection mirror 109 is too small and the reflection mirror 109 stands too much. Therefore, in this case, the adjustment screw 138 included in the reflection mirror adjustment mechanism 130 is turned clockwise. As a result, the reflection mirror 109 tilts in a direction that increases the upward angle (see FIG. 11). Therefore, the reflecting mirror 109 is adjusted to the correct angle by turning the adjusting screw 138 clockwise until the mark image 251 in the projector projection image overlaps the alignment target 151 formed on the ceiling surface 150. be able to.

  On the other hand, as shown in FIG. 19B, the mark image 251 in the projector projection image is displaced in the back direction of the display shelf 101 with respect to the alignment target 151 formed on the ceiling surface 150. In this case, the angle of the reflection mirror 109 is too large and the reflection mirror 109 is sleeping too much. Therefore, in this case, the adjusting screw 138 included in the reflecting mirror adjusting mechanism 130 is turned counterclockwise. As a result, the reflection mirror 109 tilts in a direction that reduces the upward angle (see FIG. 11). Therefore, the reflecting mirror 109 is adjusted to the correct angle by turning the adjusting screw 138 counterclockwise until the mark image 251 in the projector projection image overlaps the alignment target 151 formed on the ceiling surface 150. can do.

  As another form of implementation, if the angle of the reflection mirror 109 is correctly set on the ceiling surface 150, it does not overlap with the mark image 251 projected by the projector 201, but should take a predetermined positional relationship. The target 151 for alignment may be formed at the position.

  In this way, by receiving support for the angle adjustment processing of the reflection mirror 109 in step S106 shown in FIG. 18, the angle adjustment work of the reflection mirror 109 can be easily completed.

  Next, when the reflection mirror 109 is set to the correct angle, the angle of each projection mirror 110 (110a, 110b, 110c, 110d) is also adjusted. The angle of the projection mirror 110 (110a, 110b, 110c, 110d) can be changed as described above with reference to FIG. Therefore, here, the projection mode is selected and designated in the flowchart of FIG. 18 (Y in step S103), and image data of the projector projection image as illustrated in FIG. 17 is transmitted to the projector 201. As a result, on the back surface of each screen 106 (106a, 106b, 106c, 106d), an image edited and generated in each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the image data of the projector image is an optical system. It is guided to 108 and projected, and the image is displayed on the surface side of each screen 106 (106a, 106b, 106c, 106d). Therefore, the images displayed on the individual screens 106 (106a, 106b, 106c, 106d) are observed. Thereby, since the display position shift can be known, the angle of each projection mirror 110 (110a, 110b, 110c, 110d) is varied by the projection mirror adjustment mechanism 140 so that the shift is eliminated, and the angle adjustment is performed. To do.

  In this way, the angle adjustment work of each projection mirror 110 (110a, 110b, 110c, 110d) can be easily completed.

  As described above, each screen is adjusted by adjusting the angle of the reflection mirror 109 by the reflection mirror adjustment mechanism 130 and adjusting the angle of the projection mirror 110 (110a, 110b, 110c, 110d) by the projection mirror adjustment mechanism 140. The projector projection image projected by the projector 201 on 106 (106a, 106b, 106c, 106d) can be correctly displayed. On the other hand, the angle adjustment operations of the reflection mirror 109 and the projection mirror 110 (110a, 110b, 110c, 110d) are all operations performed by removing the back panel 120 from the base 103 and starting from the back of the base 103. Therefore, at this time, the display shelf 101 is not installed at a predetermined installation position. The display shelf 101 is installed at a predetermined installation position after adjusting the angle of the reflection mirror 109 and the projection mirror 110 (110a, 110b, 110c, 110d) and attaching the back panel 120 to the back surface of the base 103. become. For this reason, when the display shelf 101 is installed at a predetermined installation position, there is a possibility that the base 103 is distorted due to the difference in smoothness of the installation surface, and the position of the projector projection image is displaced. Alternatively, since the distortion of the base body 103 may be caused by secular change, there is a possibility that the position of the projector projection image is displaced with time. Therefore, in the display shelf system 11 according to the present embodiment, individual corrections in the image data of the projector image are performed as correction processing executed by selecting and specifying the correction mode in the flowchart of FIG. 18 (Y in step S105, step S106). The user is provided with a process for adjusting the display position and display size of the display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4). In this process, the numerical values of the display correction file 354 defining the display position and display size of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the image data of the projector image together with the display reference file 353 shown in FIG. It is done by rewriting. Hereinafter, such correction processing will be described in detail with reference to FIGS.

  First, in order to execute the process of adjusting the display position and display size of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the image data of the projector image, the front panel 121 of the display shelf 101 is opened, The part 302 is taken out and exposed to the outside. Then, a display 303, a keyboard 304, and a pointing device 305 are connected to the main body 302.

  FIG. 20 is a schematic diagram illustrating an example of a correction screen displayed on the display 303 of the computer 301 in the correction mode (see step S106 in FIG. 18). On the correction screen, the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) are displayed in white, for example, and the other areas are blacked out. The white display and the blackout are examples, and the display area IMGA and other areas may be displayed in different colors or other modes as long as they are visually distinguishable. Each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) displayed on the display 303 can be independently changed in display position and display size. In the present embodiment, a process for changing the display position and display size of the display area IMGA by operating the keyboard 304 will be described based on the flowchart shown in FIG. Before that, a display reference file 353 and a display correction file 354 for determining the display position and display size of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) will be described in detail with reference to FIGS.

  FIG. 21 is a schematic diagram illustrating an example of the display reference file 353. Definitions of “ID”, “X”, “Y”, “Width”, “Height”, “HorizontalFlip”, and “VerticalFlip” in the display reference file 353 are as shown in Table 1.

  As shown in Table 1, the definitions of “ID”, “X”, “Y”, “Width” and “Height” are int (integer) types, and the definitions of “HorizontalFlip” and “VerticalFlip” are bool (true / false) It is a type.

  In the display reference file 353 shown in FIG. 21, a numerical value enclosed by <ID> and <ID> means a shelf. Therefore, this shelf specifies any one of the display areas IMGA1, IMGA2, IMGA3, and IMGA4. The numerical value surrounded by <X> and <X> that follows is the X coordinate of the display area IMGA, and the numerical value surrounded by <Y> and <Y> is the Y coordinate of the display area IMGA. The numerical value surrounded by <Width> and <Width> defines the width of the display area IMGA, and the numerical value surrounded by <Height> and <Height> defines the height of the display area IMGA, respectively. . Therefore, the numerical value surrounded by <X> and <X> and the numerical value surrounded by <Y> and <Y> are the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image. The display position definition specifies the display position. In addition, the numerical value surrounded by <Width> and <Width> and the numerical value surrounded by <Height> and <Height> are the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image. This is the display size definition that specifies the display size. Then, true between <HorizontalFlip> and <HorizontalFlip> defines horizontal inversion display, and false defines horizontal non-inversion display. Similarly, true between <VerticalFlip> and <VerticalFlip> defines vertical inversion display, and false defines vertical non-inversion display.

  FIG. 22 is a schematic diagram illustrating an example of the display correction file 354. In the display correction file 354, definitions of “ShelfBoardID”, “DiffX”, “DiffY”, “DiffHeight”, and “DiffWidth” are as shown in Table 2.

  As shown in Table 2, the definitions of “ShelfBoardID”, “DiffX”, “DiffY”, “DiffHeight”, and “DiffWidth” are all int (integer) types.

  In the display correction file 354 shown in FIG. 22, a numerical value enclosed by <ShelfBoardID> and <ShelfBoardID> means a shelf to be adjusted. Therefore, the shelf to be adjusted specifies any one of the display areas IMGA1, IMGA2, IMGA3, and IMGA4. The numerical value surrounded by <DiffX> and <DiffX> that follows is the offset value of the X coordinate of the display area IMGA, and the numerical value surrounded by <DiffY> and <DiffY> is the display area IMGA. The offset value of the Y coordinate of <DiffHeight> and <DiffHeight> is the numerical value enclosed by <DiffHeight>, the offset value of the display area IMGA, and the numerical value enclosed by <DiffWidth> and <DiffWidth> is its display The offset value of the width of the area IMGA is defined respectively. Therefore, the numerical value enclosed by <DiffX> and <DiffX> and the numerical value enclosed by <DiffY> and <DiffY> are the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image. The display position definition specifies the display position. In addition, the numerical value surrounded by <DiffHeight> and <DiffHeight> and the numerical value surrounded by <DiffWidth> and <DiffWidth> are the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image. This is the display size definition that specifies the display size.

  FIG. 23 is a flowchart showing a flow of correction processing executed by the computer 301 in the correction mode in accordance with a program described in the image forming projection software 351. That is, the process shown in FIG. 23 shows the details of the correction process in step S106 in the flowchart of FIG.

  When the correction mode is started, the CPU 307 first executes a data reading process for the display reference file 353 (step S201), and then executes a data reading process for the display correction file 354 (step S202). In these reading processes, a process of temporarily storing the display reference file 353 and the display correction file 354 in the work area of the RAM 309 is executed.

  Then, the CPU 307 displays the correction screen illustrated in FIG. 20 on the display 303 in a routine different from the routine shown in the flowchart of FIG. The correction screen displayed at this time has individual display areas IMGA (IMGA1, IMGA2) with display positions and display sizes according to the data of the display reference file 353 and the display correction file 354 temporarily stored in the work area of the RAM 309. , IMGA3, IMGA4) are displayed in white. The CPU 307 executes a data transmission process for transmitting the image data of the correction screen to the projector 201 in a routine different from the routine shown in the flowchart of FIG. Thereby, the projector 201 projects a projector projection image based on the image data of the correction screen from the lens 202. As a result, display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) displayed in white on the correction screen are displayed on the individual screens 106 (106a, 106b, 106c, 106d) of the display shelf 101. As a result, the operator of the computer 301 that executes the correction process visually recognizes the correction result on the correction screen displayed on the display 303 as the display result displayed on each screen 106 (106a, 106b, 106c, 106d). You can see and confirm.

  In the flowchart shown in FIG. 23, as a process subsequent to step S202, a process of setting shelf = −1 is executed (step S203). The numerical value specified by “shelf =” here is a numerical value surrounded by <ShelfBoardID> and <ShelfBoardID> in the display correction file 354 shown in FIG. 22, that is, a shelf to be adjusted (adjustment target display panel). Means. When this numerical value is -1, the image forming projection software 351 defines that no shelf (adjustment target display panel) is selected.

  After step S203, the CPU 307 waits for key input from the keyboard 304 (step S204). Therefore, when any key is pressed down from the keyboard 304, the CPU 307 acquires the key code of the pressed key (step S205), whether the key specified by the key code is a numeric key, or other It is determined whether the key has been entered (step S206).

  If the CPU 307 determines that the pressed key is a numeric key as a result of the determination in step S206, the CPU 307 stores the numerical value specified by the key code in the work area of the RAM 309 as temp (step S207). Then, it is determined whether the stored numerical value is valid or invalid (step S208). That is, the CPU 307 identifies the respective screens 106 (106a, 106b, 106c, 106d) on the configuration in which the display shelf 101 has four screens 106 (106a, 106b, 106c, 106d). It is determined to be valid only when it is determined that any numerical value of 3, 4, is stored, and otherwise, it is determined to be invalid. In the case of invalidity determination, the process returns to the key input waiting in step S204. On the other hand, when the CPU 307 determines that it is valid, it sets shelf = temp (step S209). That is, the numerical value specified by the key code acquired in step S205 and stored as temp in the RAM 309 is set as a shelf (adjustment target display panel) to be adjusted. Then, the CPU 307 controls the display 303 to emphasize the display of the display area IMGA corresponding to the shelf in each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) displayed in white on the correction screen. indicate. For example, the highlighting is performed by changing the display color of the white display to another color or by blinking.

  FIG. 24 is a schematic diagram illustrating an example of the screen transition of the correction screen displayed on the display 303 of the computer 301 in the correction mode. FIG. 24 shows a state where the display area IMGA3 is highlighted.

  Returning to the flowchart of FIG. If the CPU 307 determines that the pressed key is not a numeric key as a result of the determination in step S206, the CPU 307 checks whether the numerical value specified by shelf = is -1 (step S211), and shelf = -1. In this case, the process returns to the key input waiting in step S204. This is because when shelf = −1, the shelf to be adjusted (adjustment target display panel) is not selected, and the selection is awaited.

  If the CPU 307 confirms that shelf = -1 is not satisfied in step S211, the CPU 307 determines the type of key specified by the key code acquired in step S205 (step S212).

  If the CPU 307 recognizes that the arrow key has been pressed by the determination in step S212, the display corresponding to the shelf (adjustment target display panel) to be adjusted determined by setting shelf = temp in step S209. The area IMGA is moved one dot in the direction of the arrow key (step S213). At this time, the CPU 307 temporarily stores offset data of the display position accompanying the movement in the work area of the RAM 309. In other words, the offset value in this case is the shelf level (adjustment target display panel) that is the adjustment target determined by setting shelf = temp in step S209 in the display correction file 354 shown in FIG. For a shelf set between <ShelfBoardID> and <ShelBoardID>, it is enclosed by <DiffX> and <DiffX> and the X coordinate value and <DiffY> and <DiffY>. It is set as the numerical value of the Y coordinate. Then, the process returns to the key input waiting in step S204.

  When the CPU 307 recognizes that the shift + arrow key has been pressed by the determination in step S212, the CPU 307 corresponds to the shelf (adjustment target display panel) to be adjusted by setting shelf = temp in step S209. The display area IMGA is enlarged or reduced in the direction of the arrow key (step S214). At this time, the CPU 307 temporarily stores display size offset data, which is enlargement or reduction, in the work area of the RAM 309. In other words, the offset value in this case is the shelf level (adjustment target display panel) that is the adjustment target determined by setting shelf = temp in step S209 in the display correction file 354 shown in FIG. For the shelf set between <ShelfBoardID> and <ShelfBoardID>, it is enclosed by <DiffHeight> and <DiffHeight> and the height value surrounded by <DiffWidth> and <DiffWidth> Set as a numeric width. Then, the process returns to the key input waiting in step S204.

  If the CPU 307 recognizes that the ctrl + S key has been pressed by the determination in step S212, the CPU 307 sets the offset data temporarily stored in the work area of the RAM 309 in step S213 and step S214 in the display correction file 354 (step S215). Then, the process returns to the key input waiting in step S204.

  If the CPU 307 recognizes that the Enter key has been pressed as a result of the determination in step S212, the display corresponding to the shelf (adjustment target display panel) to be adjusted determined by setting shelf = temp in step S209. The highlighting performed in step S210 on the area IMGA is canceled (step S216). Then, shelf = −1 is set, and no shelf (adjustment target display panel) is selected (step S217). Then, the process returns to the key input waiting in step S204.

  If the CPU 307 recognizes that the ctrl + Q key has been pressed by the determination in step S212, it ends the correction mode.

  As described above, the data correction processing for independently changing the display position of the display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image is executed by the processing in step S213 and the processing in step S215. . In addition, the data correction processing for independently changing the display size of the display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image is executed by the processing in step S214 and the processing in step S215.

  Note that the key type determined in step S212 that designates execution of the processes in steps S213 to S216 is merely an example. The execution of the processes in steps S213 to S216 may be designated by another type of key, or may be designated by an operation designation with the pointing device 305.

  FIG. 25 is a schematic diagram illustrating an example of display coordinates on the display 303. Here, why setting the offset value in the display correction file 354 changes the display position and display size of the display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) in the projector image independently. Will be described.

  As illustrated in FIG. 25, it is assumed that a display controller (not shown) of the display 303 controls display of the display 303 in a coordinate system of X = 0 to 1024 and Y = 0 to 768. Then, the CPU 307 assumes the reference coordinates and reference size (width, height) of the display content on the display 303 as shown in Table 3.

  “BaseX”, “BaseY”, “BaseWidth”, and “BaseHeight” in this assumption are defined as “X”, “Y”, “Width”, and “Height” in the display reference file 353 shown in FIG. The numerical value is applied.

  Further, the CPU 307 assumes the offset amount of the display position and the offset amount of the display size as shown in Table 4.

  “DiffX”, “DiffY”, “DiffWidth” and “DiffHeight” in this assumption are defined as “DiffX”, “DiffY”, “DiffHeight” and “DiffWidth” in the display correction file 354 shown in FIG. The numerical value is applied.

  Further, the CPU 307 assumes the display position and display size after the correction reflection as shown in Table 5.

  Then, under the above assumption, the CPU 307 sets the display coordinates of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4) after the correction reflection as shown in Table 6 and controls a display controller (not shown). To do.

  As a result, the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) are offset values defined as “DiffX”, “DiffY”, “DiffHeight”, and “DiffWidth” in the display correction file 354 shown in FIG. Is displayed at the display position and display size reflecting the above.

  As described above, according to the computer 301 of the present embodiment, it is possible to adjust the display position and display size of each display area IMGA (IMGA1, IMGA2, IMGA3, IMGA4). As an example, the display positions of the individual display areas IMGA (IMGA1, IMGA2, IMGA3, IMGA4) with respect to the individual screens 106 (screens 106a, 106b, 106c, 106d) due to individual differences of the display shelf 101 and their secular change. When the size is shifted, it is a very effective solution to eliminate the deviation. As a result, it is possible to correctly align a single projector projection image projected from the projector 201 with respect to a structure of a plurality of transmissive screens 106 (screens 106a, 106b, 106c, 106d). It is possible to display a projector projection image on the screen 106 (screens 106a, 106b, 106c, 106d) without positional deviation.

It is a perspective view of a display shelf which shows one embodiment of the present invention. It is the whole vertical side view which shows the display shelf which comprises a display shelf system, a projector, and a computer (projector image transmission apparatus) with the internal structure of a display shelf. It is a disassembled perspective view of a display shelf. It is a rear view of the base | substrate of a display shelf. It is a perspective view which shows the attachment or detachment structure for attaching a mounting base with respect to a base | substrate so that height adjustment is possible. It is a perspective view which shows another example of the attachment or detachment structure for attaching a mounting base with respect to a base | substrate so that height adjustment is possible. As another example shown in FIG. 6, (a) is a side view of the mounting table showing a state before being restricted by the stopper pin, and (b) is a side view of the mounting table showing a state where the position is restricted by the stopper pin. FIG. FIG. 7 is a perspective view showing a stopper pin height adjustment structure as another example shown in FIG. 6. It is a perspective view which decomposes | disassembles and shows the reflection mirror adjustment mechanism for adjusting the angle of a reflection mirror. It is a vertical side view which decomposes | disassembles and shows a reflective mirror adjustment mechanism. It is a side view of the reflection mirror adjustment mechanism for explaining the angle adjustment work of the reflection mirror. It is a perspective view which decomposes | disassembles and shows the projection mirror adjustment mechanism for adjusting the angle of a projection mirror. It is a vertical side view which decomposes | disassembles and shows a projection mirror adjustment mechanism. It is a side view of the projection mirror adjustment mechanism for demonstrating the angle adjustment operation | movement of a projection mirror. It is a block diagram which shows the hardware constitutions of the computer which transmits image data to a projector. It is a schematic diagram which illustrates the mechanism on the computer for editing and producing the image data used as the basis of the projection image of a projector, and making it project on a projector. It is a schematic diagram which shows an example of the projector image edited and produced on the computer used as the foundation of the projector projection image which a projector projects. It is a flowchart for demonstrating the switching process between the edit mode, projection mode, and correction mode which a computer performs according to the program described in image formation projection software. It is a schematic diagram for demonstrating the angle adjustment method of a reflective mirror, (a) is a mark image in a projector projection image with respect to the alignment target formed in the ceiling surface of a base | substrate, The front direction of a display shelf FIG. 6B is a schematic diagram showing an adjustment method when the position is displaced (turning the adjustment screw clockwise); FIG. 5B is a diagram showing a position in the projector projection image with respect to an alignment target formed on the ceiling surface of the substrate. It is a schematic diagram which shows the adjustment method (turning an adjustment screw counterclockwise) when the mark image is displaced in the back direction of the display shelf. It is a schematic diagram which shows an example of the correction | amendment screen displayed on the display of a computer at the time of correction | amendment mode. It is a schematic diagram which shows an example of a display reference file. It is a schematic diagram which shows an example of a display correction file. It is a flowchart which shows the flow of the correction process which a computer performs in correction | amendment mode according to the program described in the image formation projection software. It is a schematic diagram which shows an example of the screen transition of the correction | amendment screen displayed on the display of a computer at the time of correction | amendment mode. It is a schematic diagram which shows an example of the display coordinate on a display.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Display shelf system, 101 ... Display shelf, 102 (102a, 102b, 102c) ... Mounting stand, 103 ... Base | substrate, 106 (106a, 106b, 106c, 106d) ... Screen, 107a ... Projector installation part, 109 ... Reflection mirror , 110 ... Projection mirrors (110a, 110b, 110c, 110d), 118 ... Connection arm (connection structure), 130 ... Reflection mirror adjustment mechanism, 140 ... Projection mirror adjustment mechanism, 201 ... Projector, 301 ... Computer (projector image transmission device) , 303 ... Display (display unit), 306 ... Microcomputer (control unit), 309 ... RAM (storage unit), 311 ... HDD (storage unit), 314 ... Communication interface (data transmission unit), 353 ... Display reference file (Display file), 354... Display correction file Le (display file), A ... goods (goods), IMGA (IMGA1, IMGA2, IMGA3, IMGA4) ... display area, FS ... the first space, SS ... the second space

Claims (10)

A base that forms a first space therein;
A second space that extends in the horizontal direction and is disposed on the front surface of the base and communicates with the first space is formed therein, and an article can be placed on the top surface, at least one of which is attached to the base A multi-stage mounting table, the height position of which is variably mounted;
A plurality of transmissive screens that are positioned in a front region of each of the mounting tables and that can project a projector projection image projected from the rear surface side that is the second space side to the front surface side;
A projector installation unit provided at a position below the first or second space for arranging a projector for projecting a projector projection image;
A plurality of non-overlapping partial areas of one-screen projector projection image projected by the projector guided upward in the first space are individually reflected toward the second space to reflect the screen. A plurality of projection mirrors projected on the back side;
The mounting table, the height of which is variably attached to the base, and the projection mirror that projects the projector projection image toward the screen provided on the mounting table are integrally connected. A connection structure that allows the height position of the projection mirror to be variable along with the mounting table;
Display shelf with.   The display shelf according to claim 1, further comprising a projection mirror adjustment mechanism that adjusts an angle of the projection mirror. The projector placement unit arranges the projector horizontally,
A reflection mirror that reflects the projector projection image projected from the projector upward and guides it to the projection mirror;
The display shelf according to claim 1 or 2.   The display shelf according to claim 3, further comprising a reflection mirror adjustment mechanism that adjusts an angle of the reflection mirror. A display shelf according to any one of claims 1 to 4,
A projector image transmitting device for transmitting image data to the projector;
With
The projector image transmission device includes:
A data transmission unit for performing data transmission to the projector;
A data transmission process in which display data corresponding to each of the screens is independently set and image data of a projector image forming the basis of the projector projection image is transmitted to the projector by the data transmission unit; A data correction process for independently changing the display position of the display area;
Comprising
Display shelf system. The setting of the display area is made by a display position definition that specifies a display position of the display area in the projector image defined in a display file stored in a storage unit accessible by the control unit,
The change of the display position of the display area is performed by changing the display position definition defined in the display file.
The display shelf system according to claim 5. A display shelf according to any one of claims 1 to 4,
A projector image transmitting device for transmitting image data to the projector;
With
The projector image transmission device includes:
A data transmission unit for performing data transmission to the projector;
A data transmission process in which display data corresponding to each of the screens is independently set and image data of a projector image that forms the basis of the projector projection image is transmitted to the projector by the data transmission unit; A data correction process for independently changing the display size of the display area;
Comprising
Display shelf system. The setting of the display area is made by a display size definition that specifies a display size of the display area in the projector image defined in a display file stored in a storage unit accessible by the control unit,
The display size of the display area is changed by changing a display size definition defined in the display file.
The display shelf system according to claim 7. The projector image transmission device can be connected to a display unit that displays information under the control of the control unit,
In the correction process, the control unit displays the projector image on the display unit with a display area corresponding to each screen, and displays a change corresponding to the operation of the input unit on the display unit. The display shelf system according to claim 5, which is reflected in a projector image.   The display shelf system according to claim 9, wherein the control unit transmits the projector image displayed on the display unit to the projector by the data transmission unit during the correction process.

Images