DE4428528A1 - Fall sheet display module - Google Patents

Abstract

The display module has information-carrying sheets (5) attached to a horizontal-axis rotor (4) behind the screen (6), which can be pulled off or pivoted for access when the rotor is to be withdrawn from its housing (3). The drive unit (2) is associated with a sheet controller (11) which is used to turn the rotor into its service position for withdrawal. When the rotor is reassembled into the housing, the controller sets the sheets automatically into their basic position.

Description

The invention relates to a falling sheet display module according to the preamble of claim 1.

Fall sheet display modules are particularly useful in case sheet indicators used. Fall sheet indicators serve the Display of information, for example about the permanent changing display of place names and times for the display of the departure and arrival of trains, Ships and the arrival or departure of aircraft.  

In the controlled displays, the fall sheets must be included the information is moved quickly to within to change the display in the shortest possible time. The height mechanical stress on the falling leaves and the Contact with the environment make continuous maintenance of the fall leaves necessary.

DE 42 27 881 A1 is a fall leaf indicator described, in which the rotor unit with the case scroll is interchangeably stored in the housing. The The rotor unit can move out of the housing towards the front to be pulled. To remove the rotor unit, need a side and an intermediate part and that Drain profile can be removed. The replacement of the Rotor unit for the purpose of maintenance or for the purpose of changing the fall leaves is with a Disassembly and assembly work connected. The basic one position of the fall leaves after dismantling and Assembly is done manually.

The invention is therefore based on the object a fall sheet display module of the generic type to change so that a quick removal the entire rotor unit in just a few steps is possible and that when mounting the fall sheet display module an automatic basic setting of the Fall leaves are done.

To achieve this object, the invention provides that the fall leaf rotor from the through a joint defined service position is taken after an aperture unlocked and forward 90 °  was pivoted or removed entirely. The bearings of the fall leaf rotor are two in each case shared that the bearings were partly in one Basic body and the remaining part in the panel are formed so that after removal of the aperture, the Rotor can be removed. The fall leaf rotor is controlled by a fall sheet control in the service position. The service position of the fall sheet is by means of joining elements on the rotor shaft and defined on the output gear. One of the verries gelungseinrichtung is in the upper area of the panel arranged and is with a simple tool operated. The other locking devices are detachable without tools and offer increased security Ness. The drive unit is essentially by a synchronous motor and the fall sheet control educated. The type of engine ensures an almost Starting and stopping the falling sheet without delay rotors. To record the position of the falling sheet, a optoelectronic pulse counting method used due to the non-contact components is wear and maintenance free and no after adjustment after a single, correct electrical and mechanical adjustment required.

Further advantageous embodiments of the invention result from the subclaims.

The invention is based on an off example of a fall sheet display module closer explained. In the accompanying drawing:  

Fig. 1 is a side view of the Flip-over display module in exploded view;

Fig. 2 shows the side view of the diaphragm according to the representation in Fig. 1,

Fig. 3 is a bottom view of the visor according to Fig. 2,

Fig. 4 is a side view of the Flip-over display module according to Fig. 1 without the case-blade rotor with different positions of the aperture,

Fig. 5 is a cut-away view of the upper locking aperture,

Fig. 6 is a side view of the drive unit in an exploded view,

Fig. 7 is a block diagram of the case of sheet control,

Fig. 8 and the top view of the falling sheet display module

Fig. 9 shows a sectional view of the bearing points of the rotor blade case along the line AA according to Fig. 8.

FIG. 1 is a Flip-over display module 1 is substantially of a drive unit 2 having a case, blade control 11, a housing 3, a rotatably mounted flip-over rotor 4 consisting of a rotor shaft 12, receiving rollers and the case scroll 5, and a diaphragm 6 is formed.

The fall sheet display modules 1 are constructed in different sizes as plug-in modules, each with a uniform interface. The inserted fall sheet display modules 1 can be snapped into the carrier of a slide-in frame (not shown). The different fall sheet display modules 1 constructed in a uniform grid are lined up side by side and one above the other in the just-rasterized slide-in frame to form a closed display field (not shown).

To replace a fall leaf rotor 4 , this is brought into its service position via the fall leaf control 11 .

The service position of the fall-leaf rotor 4 is, as can be seen from FIG. 1, by a joint between a U-shaped receptacle 13 on an output gear 14 ( FIG. 6) and a mushroom-shaped shape 15 on the rotor shaft 12 that can be positively fitted into the receptacle 13 , formed ( Fig. 8, 9). In this position, the falling leaf rotor 4 can be pulled out to the front after pivoting or removing the cover 6 .

FIG. 2 shows the enlarged side view of the panel 6 as shown in FIG. 1. The panel 6 is formed from two side walls 16 , each of which merges into a lower web 17 , which is connected to a locking plate 19 via a film hinge 18 is. The locking plate 19 connects the side walls 16 in the lower area, a web 20 connects the side walls 16 in the upper area. From the web 20 in the upper region of the diaphragm 6 , two latching noses 21 are formed inward at a 90 ° angle. According to FIG. 3, the locking plate 19 has a depression 28 on the underside with a lower guide groove 29 and on the top side a locking bar, not shown. The side walls 16 contain bevels 22 , the lower bevel 22 being formed with a receptacle 23 . Both bevels 22 further contain slots (not shown) in their end faces 24 . The respective end face 25 of the side walls 16 has a further receptacle 26 . From the end faces 24 of the side walls 16 , substantially semicircular recesses 27 for the bearing points of the fall leaf rotor 4 are formed .

FIG. 4 shows the side view of the Fallblattan see module 1 without the case-bladed rotor 4 with ver different positions of the shutter 6. The panel 6 is connected to the housing 3 via the locking plate 19 and can be pivoted forwards by 90 ° via the film hinges. The detent plate 19 is inserted between a plate 37 and a plate 37 connected thereto through a web 38 of disc-shaped latching lug 39 (Fig. 1). The locking plate 19 is guided via the guide groove 29 ( FIG. 3) and a guide web 40 on the plate 37 ( FIG. 1), while the locking between the locking lug 39 and the locking web, not shown, takes place on the locking plate 19 of the panel 6 .

In the locked position, the cover 6 is locked several times with the housing 3 . The first locking is formed via the latches 21 of the panel 6 and the receiving slots 30 in the housing 3 as shown in FIG. 5. This locking can be released using a simple tool 31 .

A second locking takes place via the slots (not shown) in the bevel 22 of the panel side walls 16 , into which webs 32 engage on the bevels 33 in the housing wall 34 ( FIG. 4).

A further locking takes place via the receptacles 26 , 33 in the end face 25 and on the bevel 22 of the panel 6 ( FIG. 2), engage in the knobs 35 , 36 on the end face and on the bevel 33 in the housing wall 34 ( FIG . 4). These locks can be released without tools.

Fig. 6 shows an exploded view of the side view of the drive unit 2. The drive unit 2 consists of the motor 41 , on the shaft 43 of which the pulse disk 9 is applied, of the synchronous wheel 10 , the intermediate gearwheels 42 , the driven gearwheel 14 and the fall sheet control 11 built on a printed circuit board. The gear wheels 42 , 14 and the synchronizer wheel 10 are in engagement with one another and are mounted in a side wall 7 and in an intermediate part 8 .

The synchronous motor 41 used for the drive unit 2 drives the fall leaf rotor 4 for positioning via a reduction gear 50 ( FIG. 7). The type of motor ensures that the fall-leaf rotor 4 starts and stops almost without delay. An optoelectronic pulse counting method is used to record the fall sheet position. This type of position detection is wear-free and maintenance-free due to the non-contact components and does not require readjustment after a single, correct electrical and mechanical adjustment. The falling sheet position is determined by counting pulses from the rotating pulse disk 9 and a synchronizing pulse from the synchronizing wheel 10 ( FIG. 6).

The response time between two positions is 60 ms in the exemplary embodiment, so that, for example, the response time of 1.2 seconds is required for positioning from position 1 to position 21. The adjustment of the falling leaves 5 is done automatically. If the falling sheet display module 1 is to be changed, it must be brought into the service position via the control 11 .

FIG. 8 shows a top view of the front area of the fall sheet display module 1, the bearing points of the fall sheet rotor 4 and the joint with the formation 15 and the receptacle 13 .

FIG. 9 shows the assignment of the most important parts of the bearing points of the fall-leaf rotor 4 from the sectional illustration along the line AA in FIG. 8. The side views of a part of the intermediate part 8 , the mushroom-shaped shape 15 on the rotor shaft 12 and the diaphragm 6 are shown in an exploded view. The rotor shaft 12 of the fall leaf rotor 4 with the receiving wheel 53 for the fall leaves 5 is partly on the upper side in FIG. 8 in the intermediate part 8 , into which the driven gear 14 is inserted, and on the other part in the diaphragm 6 . The side wall 7 is also included in this bearing point.

The vertical division of the bearing point of the rotor 4 is designed in the output gear 14 as a U-shaped receptacle 13 into which the mushroom-shaped shape 15 on the rotor shaft 12 is positively fitted, the "mushroom cap" being fitted into the second bearing half in the diaphragm 6 .

The lower side of the bearing point of the rotor 4 in FIG. 8 is also divided vertically and is inserted in the housing wall 34 and the other half in the diaphragm 6 .

The fall sheet control 11 is shown in Fig. 7 as a block diagram of the functional modules. The falling sheet control 11 is formed from a microcontroller 45 with non-volatile read / write memory 52 , a voltage stabilization 46 , a zero crossing detector 47 , a circuit breaker 48 and reflex couplers 49 , 51 with controls.

With the voltage stabilization 46 , a 5 V supply voltage U _{b is obtained} from the 10 to 12 V system voltage U_. The zero voltage detector 47 tells the microcontroller 45 whether the drive AC voltage U _{∼ is} at the zero crossing N.

The circuit breaker 48 switches the motor 41 on and off.

The reflex couplers 49 , 51 including the controls K1, K2 have the task of recognizing certain gear positions in the transmission 50 in order to be able to infer the exact position of the falling-leaf rotor 4 therefrom.

The microcontroller 45 with the non-volatile read / write memory 52

• controls the motor 41 via the circuit breaker 48 ,
• - evaluates the zero crossings N,
• controls the reflex couplers 49 , 51 and evaluates their output signals K1, K2,
• - storing module-specific information (transmission position relative to the reference position on the rotor case, sheet 4, at the current case bladed rotor 4, a displayed icon, etc.),
• - continuously executes and generates self-test functions Status information,
• - communicates with the higher-level control using an asynchronous serial data connection.

In order to be able to display a character on a falling sheet display module 1 , the microcontroller 45 must have information as to which position of the gear 50 leads to the display of the desired character on the falling sheet rotor 4 . Since the assembly of the toothed wheels 42 , 14 , 10 takes place in any position, each module 1 must be adjusted. Three input variables are used to determine the actual position of the fall leaf rotor 4 .

The first input variable is the synchronization pulse K1 at the output of the reflex coupler 49 . This pulse K1 is generated exactly once per revolution of the falling-leaf rotor 4 . The microcontroller 45 uses this pulse K1 to calculate the character shown on the falling leaf rotor 4 .

The second input variable is formed by the leaf pulses K2 on the reflex coupler 51 . The leaf pulses K2 are generated exactly once per leaf fall. The micro controller 45 obtains from these pulses K2 the information as to whether the fall leaf rotor 4 has rotated through the angle that corresponds to a falling leaf.

The third input variable is the zero crossings N of the AC drive voltage U _∼ at the zero crossing detector 47 . The microcontroller 45 uses these signals N in order to fine-tune the falling-leaf rotor 4 . The leaf pulses K2 drop in any assembly of the transmission 50 is not with the rest position of the rotor case sheet 4 together.

The aim of the adjustment is to have the microcontroller 45 calculate and save its own gear position with respect to the pulses K1, K2, N at a known rotor position. For this purpose, the falling sheet display module 1 is brought into the “adjustment” operating mode using suitable means. The now rotating falling sheet display module 1 then receives information from the outside when the falling sheet rotor 4 is in the reference position. The falling sheet display module 1 stores, for example, that the reference position is at a distance (15 × K2) + (3 × N) from K1.

With all subsequent setting commands, the falling sheet display module 1 can use the stored information to calculate the true position of the falling sheet rotor 4 and set the correct character. According to the example chosen, the third character would be at a distance (18 × K2) + (3 × N) from K1.

In normal operation, the microcontroller 45 communicates with the higher-level control and uses the input variables described to set the required character or reports the result of the self-tests or the set character to the higher-level control.

Reference list

01 module
2 drive unit
3 housing
4 fall leaf rotor
5 fall leaves
6 aperture
7 side wall
8 intermediate part
9 pulse disk
10 synchronous wheel
11 Fall sheet control
12 rotor shaft
13 recording
14 output gear
15 formation
16 panel side wall
17 bridge
18 film hinge
19 locking plate
20 bridge
21 latch
22 bevel
23 recording
24 end face
25 end face
26 recording
27 recess
28 deepening
29 guide groove
30 slot
31 tools
32 bridge
33 bevel
34 housing wall
35 knobs
36 knobs
37 plate
38 footbridge
39 latch
40 guide bridge
41 engine
42 intermediate gear
43 wave
44
45 microcontrollers
46 Voltage stabilization
47 zero crossing detector
48 circuit breakers
49 reflex coupler
50 gears
51 reflex coupler
52 memories
53 pick-up wheel
K1 sync pulse
K2 leaf pulse
N zero crossing.

Claims (10)

1. Fall sheet display module for changing the display of information of all kinds, consisting of a drive unit ( 2 ), a housing ( 3 ), a rotatably mounted fall sheet rotor ( 4 ) with a fall sheet ( 5 ), the fall sheet rotor ( 4 ) from a defined position Can be removed from the front of the housing ( 3 ), characterized in that the fall-leaf rotor ( 4 ) can be replaced from the defined position after removal of an aperture ( 6 ), the bearing points for the fall-leaf rotor ( 4 ) each being divided in two such that the Bearing points are formed in part in a basic body ( 3 , 8 ) and the remaining part in the diaphragm ( 6 ), and that the drive unit ( 2 ) contains a fall sheet control ( 11 ) for automatic basic setting of the position of the fall sheets ( 5 ). 2. Fall sheet display module according to claim 1, characterized in that the bearings for the case blade rotor ( 4 ) on one side by an intermediate part ( 8 ) and the panel ( 6 ) and on the other side by the housing ( 3 ) and the panel ( 6 ) are formed. 3. Fall leaf display module according to claim 1, characterized in that the defined position of the fall leaf rotor ( 4 ) by a joint consisting of a U-shaped receptacle ( 13 ) on an output gear ( 14 ) and one in the receiving ( 13 ) positively fit mushroom-shaped shape ( 15 ) is formed on the rotor shaft ( 12 ). 4. Fall sheet display module according to claim 1, characterized in that the diaphragm ( 6 ) on the housing ( 3 ) below and / or above is tiltably attached and locking devices ( 21 , 30 ; 32 , 35 , 36 , 23 , 26 ). 5. Falling sheet display module according to claims 1 to 4, characterized in that the diaphragm ( 6 ) on the housing ( 3 ) is resiliently latched at the bottom and can be tilted via film hinges ( 18 ) and via slots ( 30 ) in the upper housing edge, into the latching lugs ( 21st ) engage on the upper edge of the panel, and is locked several times via webs ( 32 ) and knobs ( 35 , 36 ) in the housing wall ( 34 ) which engage in slots and receptacles ( 23 , 26 ) in the panel side wall ( 16 ). 6. Fall sheet display module according to claims 1 to 5, characterized in that the side walls ( 16 ) of the diaphragm ( 6 ) have bevels ( 22 ) with the slots and receptacles ( 23 , 26 ) for locking, which open into end faces ( 25 ), from which savings ( 27 ) for the bearing points of the fall leaf rotor ( 4 ) are formed, the side walls ( 16 ) above via a web ( 20 ) with the detents ( 21 ) and below via the film hinges ( 18 ) and above a locking plate ( 19 ) are connected. 7. Fall sheet display module according to claim 1, characterized in that the fall sheet control ( 11 ) for automatic basic setting of the position of the fall sheets ( 5 ) for detecting the fall sheet position contains an optoelectronic pulse counting method. 8. Fall sheet display module according to claim 7, characterized in that the fall sheet position is determined by counting pulses (K2) from a rotating pulse disc ( 9 ) and a synchronizing pulse (K1) from a synchronizing wheel ( 10 ). 9. Fall sheet display module according to claims 1 to 8, characterized in that the fall sheet rotor ( 4 ) is brought into the service position before maintenance or replacement via the fall sheet control ( 11 ). 10. Fall sheet display module according to claim 7, characterized in that the fall sheet control ( 11 ) from a microcontroller ( 45 ) with memory ( 52 ), scanning electronics ( 49 , 51 ), a voltage stabilization ( 46 ), a zero voltage detector ( 47 ) and one Circuit breaker ( 48 ) is formed on a circuit board.