EP0957046B1 - Lock for housed refuse receptacles - Google Patents

Abstract

The lock (4) is formed as a chamber lock that faces a lock chamber (6). The lock chamber volume is self-acting and continuously variable so as to adapt to the volume which is required for the disposed waste.

Description

The invention relates to a throw-in lock for housings for housing waste containers according to the preamble of claim 1. A throw-in with the features of the preamble of claim 1 is in document DE-C-19541010 disclosed.

DE-C-195 41 010 is a waste lock designed as a drum lock with a predetermined and unchangeable lock chamber volume known and arranged above the opening area in a housing Waste bin integrated in the top cover of the housing. This Waste lock is also provided with a locking device, only authorized people can use the waste containers becomes.

From DE-U-296 09 907 is a container box for receiving a garbage container known, the container box two throw-in gates with a uniform Has lock chamber volume. The volume of the lock chambers is predetermined and can therefore accommodate a defined amount of waste. An identification system ensures that the container box only by authorized persons is used, and registers the frequency of use, so that based on the defined lock chamber volume, the individually thrown-in amount of waste can be detected. Here is an exact recording of the total thrown Amount of garbage can only be expected provided that each time it is used the throw-in lock the amount of waste thrown in roughly the volume of the Lock chamber corresponds.

DE-A-196 38 749 are throw-in locks for a housing for housing known from waste containers. Each throw-in lock has a lock chamber on the through a slot with waste, such. B. trash bags, loadable is. In addition, the well-known throw-in lock is from a filling position movable into an emptying position and emptied into the waste container. To the different, brought in by the users in the waste container To be able to record large amounts of waste precisely, several of them must be Throw-in locks in different sizes with a defined capacity be provided. To be able to determine which of the different large throw-in locks the one with the maximum required capacity in the worst case, all existing throw-in locks be opened.

Starting from the prior art according to DE-A-196 38 749 the person skilled in the art faced with the task of a throw-in lock for introducing waste into one To create waste containers, the already with a single lock individual amounts of waste can be recorded exactly, so that a cost saving reached and usability is improved.

This object is achieved with the features of claim 1.

With the interlocking lock with a lock chamber with infinitely variable Chamber volume can be designed so that it over has two filling openings, each filling opening with an unlockable Closure cover is closed. Below this cover is depending on Prior use, the trough recess parked on the left or right of a fixed wall. An LED display panel can show the user the lock chamber on the right or instruct on the left, correspondingly the right or left locking latch is released. During the time a user is closing the cap opens and his garbage, for example in the form of a garbage bag, placed in the trough, is the actuating device for the movable one The plunger-forming wall is locked, as is the sliding mechanism for the trough.

After placing garbage in the lock chamber and closing it manually of the cover is the locking of the cover of Lock chamber activated automatically. The locks on the caps can be monitored by sensors so that after closing an open Cap a microprocessor a corresponding input signal is communicated, which then generates an output signal which the respective actuating device for the movable wall and for the trough unlocks. After that, the moving mechanism can move the movable wall in the lock chamber against the inserted garbage bag until one builds up defined resistance, by which the pressing process ends becomes. In this way, the unused volume of the lock chamber is optimal reduced. Depending on the design and control of the throw-in lock can translate the trough trough simultaneously with the wall forming the plunger be moved along by guides. Alternatively, this shift the trough trough is triggered even when the sensed press force is reached be so that either the pressing movement of the movable wall and the sliding movement of the trough trough triggered simultaneously or one after the other become. By moving the trough, which also the The bottom of the lock chamber forms, the bottom of the lock chamber pulled away under the inserted garbage, so that this in the below standing waste container can fall, and again a lock chamber is formed, which is available for use. By forming a lock chamber alternately on one side and on the other side of a middle one Partition wall also becomes a more even distribution of the garbage within brought about of the waste container, which accordingly improved utilization learns what reduces the cost of waste disposal.

Fig. 1

ein Gehäuse zur Einhausung mit einem darin befindlichen Abfallbehälter,

Fig. 2

die Schleusenkammer in geöffneter, d. h. befüllbarer Stellung,

Fig. 3

das Detail (X) in Fig. 1, in Vergrößerung,

Fig. 4

das Detail (Y) in Fig. 2, in Vergrößerung,

Fig. 5

einen Drehmechanismus zur Betätigung verschiedener Schleusentrommeln der Einwurfschleuse gemäß Schnitt A-A in Fig. 4,

wobei die Figuren 1 - 5 nicht zur Erfindung gehören, und

Fig. 6

ein Einhausungsgehäuse mit darin befindlichem Abfallbehälter und einer Einwurfschleuse in einer abgewandelten Ausführung,

Fig. 7

die Einwurfschleuse gemäß Fig. 6 in entriegelter, d.h. freigegebener und geöffneter Stellung,

Fig. 8

die Einwurfschleuse gemäß Fig. 6 in geschlossener Stellung mit eingelegtem Müllbeutel,

Fig. 9

die Einwurfschleuse in nach unten offener Entleerungsstellung,

Fig. 10

einen Schnitt durch die Schleusenkammer der Einwurfschleuse gemäß Einzelheit X in Fig. 6 in vergrößerter Darstellung,

Fig. 11

einen Schnitt durch die geöffnete Schleusenkammer gemäß Einzelheit Y in Fig. 7,

Fig. 12

einen Längsschnitt durch das Schleusenkammergehäuse parallel und im halben Abstand zu den Prismenführungen verlaufend,

Fig. 13

eine Ansicht in Richtung U in Fig. 12,

Fig. 14

eine Ansicht in Richtung V in Fig. 12,

Fig. 15

einen Schnitt nach der Linie A-A in Fig. 12 in vergrößerter Darstellung,

Fig. 16

einen Querschnitt durch eine Trogmulde der Einwurfschleuse nach Fig. 6,

Fig. 17

einen Schnitt nach der Linie C-C in Fig. 16,

Fig. 18

eine Ansicht der Trogmulde in Richtung W in Fig. 17,

Fig. 19

einen Längsschnitt durch eine komplette Einwurfschleuse mit eingelegtem Müllbeutel mit rechtsseitig geparkter Trogmulde,

Fig. 20

einen Schnitt nach der Linie D-D in Fig. 19 mit eingelegtem Müllbeutel,

Fig. 21

eine Ansicht der Einwurfschleuse in Richtung V in Fig. 19,

Fig. 22

einen Längsschnitt durch eine komplette Einwurfschleuse mit eingelegtem Müllbeutel in verpresstem Zustand,

Fig. 23

einen Schnitt nach der Linie D-D in Fig. 17,

Fig. 24

eine Ansicht der Einwurfschleuse in Richtung V in Fig. 22,

Fig. 25

einen Längsschnitt durch eine komplette Einwurfschleuse mit eingelegtem Müllbeutel im verpressten Zustand mit Trogmulde in linker Anschlagposition,

Fig. 26

einen Schnitt nach der Linie D-D in Fig. 25,

Fig. 27

eine Ansicht der Einwurfschleuse in Richtung V in Fig. 20,

Fig. 28

einen Längsschnitt durch eine komplette Einwurfschleuse analog zu Fig. 25, nachdem der Müllbeutel durch Zurückfahren der beweglichen Wand in den Abfallbehälter gefallen ist,

Fig. 29

einen Schnitt nach der Linie D-D in Fig. 28,

Fig. 30

eine Ansicht der Einwurfschleuse in Richtung V in Fig. 23,

Fig. 31

eine Ansicht der Einwurfschleuse in Ausgangsstellung für die Wiederholung des Beschickungsvorganges analog zu Fig. 28 mit linksseitig geparkter Trogmulde,

Fig. 32

einen Längsschnitt durch die Einwurfschleuse gemäß Fig. 6 mit eingelegtem Müllbeutel mit linksseitig geparkter Trogmulde,

Fig. 33

einen Längsschnitt durch die Einwurfschleuse mit links- und rechtsseitig der Trogmulde an dieser angekoppelten, verschiebbaren Wänden,

Fig. 34

vergrößerte Darstellung der Trogmulde gemäß Fig. 33 mit Zugfederankopplung,

Fig. 35

eine Ansicht der Trogmulde gemäß Fig. 34 mit relativ zur Trogmulde verschobener Wand.

Fig. 36

vergrößerte Darstellung der Trogmulde gemäß Fig. 33 mit Blattfederankopplung,

Fig. 37

eine Ansicht der Trogmulde gemäß Fig. 36 mit relativ zur Trogmulde verschobener Wand.

Fig. 38

prinzipieller Aufbau einer Mikroprozessorsteuerung an einem Ausführungsbeispiel einer Betätigungseinrichtung einer Mülleinwurfschleuse am Beispiel eines Spindelantriebs

Further details and effects of the invention result from the following description and the drawing, in which several exemplary embodiments of the insertion lock according to the invention are shown schematically, approximately to scale. Show it:

Fig. 1

a housing for housing with a waste container inside,

Fig. 2

the lock chamber in the open, ie fillable position,

Fig. 3

the detail (X) in Fig. 1, in an enlargement,

Fig. 4

the detail (Y) in Fig. 2, in an enlargement,

Fig. 5

4 shows a rotary mechanism for actuating various lock drums of the insertion lock according to section AA in FIG. 4,

Figures 1-5 do not form part of the invention, and

Fig. 6

a housing housing with a waste container and a throw-in lock in a modified version,

Fig. 7

6 in the unlocked, ie released and open position,

Fig. 8

6 in the closed position with inserted garbage bag,

Fig. 9

the insertion lock in the emptying position open at the bottom,

Fig. 10

3 shows a section through the lock chamber of the insertion lock according to detail X in FIG. 6 in an enlarged view,

Fig. 11

7 shows a section through the opened lock chamber according to detail Y in FIG. 7,

Fig. 12

a longitudinal section through the lock chamber housing parallel and at half the distance to the prism guides,

Fig. 13

12 shows a view in the direction U in FIG. 12,

Fig. 14

12 shows a view in the direction V in FIG. 12,

Fig. 15

12 shows a section along the line AA in FIG. 12 in an enlarged representation,

Fig. 16

6 shows a cross section through a trough trough of the insertion lock according to FIG. 6,

Fig. 17

a section along the line CC in Fig. 16,

Fig. 18

a view of the trough in the direction W in Fig. 17,

Fig. 19

a longitudinal section through a complete sluice gate with inserted garbage bag with a trough recess parked on the right,

Fig. 20

19 shows a section along the line DD in FIG. 19 with the trash bag inserted,

Fig. 21

19 shows a view of the insertion lock in the direction V in FIG. 19,

Fig. 22

a longitudinal section through a complete sluice gate with inserted garbage bag in the pressed state,

Fig. 23

a section along the line DD in Fig. 17,

Fig. 24

FIG. 22 shows a view of the insertion lock in the direction V in FIG. 22,

Fig. 25

a longitudinal section through a complete sluice gate with inserted garbage bag in the compressed state with trough recess in the left stop position,

Fig. 26

a section along the line DD in Fig. 25,

Fig. 27

20 shows a view of the insertion lock in the direction V in FIG. 20,

Fig. 28

25 shows a longitudinal section through a complete sluice gate analogous to FIG. 25 after the garbage bag has fallen into the waste container by moving the movable wall back,

Fig. 29

28 shows a section along the line DD in FIG. 28,

Fig. 30

FIG. 23 shows a view of the insertion lock in the direction V in FIG. 23,

Fig. 31

FIG. 2 shows a view of the insertion lock in the starting position for repeating the loading process analogously to FIG. 28 with the trough recess parked on the left,

Fig. 32

6 with a garbage bag inserted and a trough recess parked on the left-hand side,

Fig. 33

a longitudinal section through the sluice gate with the trough recess coupled to the left and right sides of the sliding walls,

Fig. 34

33 enlarged view of the trough trough according to FIG. 33 with tension spring coupling,

Fig. 35

a view of the trough depression according to FIG. 34 with the wall displaced relative to the trough depression.

Fig. 36

33 enlarged view of the trough depression according to FIG. 33 with leaf spring coupling,

Fig. 37

a view of the trough depression according to FIG. 36 with the wall displaced relative to the trough depression.

Fig. 38

Basic structure of a microprocessor control on an embodiment of an actuating device of a garbage disposal lock using the example of a spindle drive

In Fig. 1 is a housing 1 for housing a waste container 2 together with this shown. The housing 1 can, for example, be secured against displacement Foundation plate 11 may be connected. The waste container 2 is in the open Condition, d. H. with the cover 8 open, in the interior 14 of the Housing 1. The waste container 2 is equipped with rollers 12 and can in the interior 14 of the housing 1 by opening the rear wall 13 in and be brought out.

The upper cover 3 of the housing 1 contains a throw-in lock 4 which can be operated from the front 19 of the housing 1.

The throw-in lock 4 according to the invention consists in the embodiment according to FIG. 1 to 5 from at least two lock drums 5. A first lock drum 5 has an interior as a lock chamber 6 with an insertion opening 7 and is mounted so as to be rotatable and drivable about its axis of rotation 15. The lock chamber 6 is shown in the locked position in the starting position, i.e. it cannot be filled in this angle of rotation position since the insertion opening 7 faces the interior 14 of the housing 1.

The lock drum 5 has a rotary mechanism 16 which has a Hand lever 10 can be operated as an actuator. The lock drum 5 is protected against unauthorized persons by a locking device 17 Use secured.

2, the lock drum 5 with its lock chamber 6 is in the open position Position, i.e. shown in an angle of rotation position that a filling of the Lock chamber 6 allows, for example, a garbage bag 9 in the Lock chamber 6 can be inserted.

Fig. 3 shows the enlarged detail X in Fig. 1. The lock drum 5 is through the locking device 17 locked. The lock drum 5 can of the rotary mechanism 16 are operated. This includes a propellant drive For example, a toothed belt drive 20, which from the drive shaft 21 and two toothed belt pulleys 22, 23, which are wrapped by the toothed belt 24 are. The rotary mechanism 16 can be operated manually with the hand lever 10, which is non-rotatably connected to the drive shaft 21, are actuated. The on that Housing 1 attached locking device 17 consists of a spring-loaded Incident pawl 25, which is biased by a tension spring 26, the Incident pawl 25 with a locking stop 27 which is rotationally fixed to the drive shaft 21 is connected, is engaged.

Fig. 4 shows an enlarged detail (Y) of Fig. 2. The lock drum (5) is shown in the unlocked state in the open rotational angle position. Around To be able to bring about this angular position is the locking device 17 by means of an actuator 28 which has a magnetic coil and a Magnet plunger 29 is unlocked to operate. The magnetic plunger 29 actuates the Drop pawl (25) so that it undergoes a rotation through which the locking stop 27 of the drive shaft 21 is released for rotation.

The locking mechanism 17 can only be unlocked if one preferably system recognition comprising a microprocessor, for example activated via a transponder that interacts with a first input signal generated with the microprocessor, the user in the form of the user ID accepted.

If the user is accepted, this can be an initiator 30, which for example can be designed as a push button or capacitive proximity switch, activate, which forms a second input signal for the microprocessor, the now generates an output signal which sets the actuator 28 in motion, so that the latch 25 is actuated and the locking device 17 unlocked becomes. The output signal for actuating the actuator 28 is time-limited as an input signal fed back to the microprocessor, so that this signal changes into self-holding for a predetermined period of time. After this time has elapsed, the prestressed tension spring 26 is now actuated the incident pawl 25 against the direction of actuation of the magnetic plunger 29, so that the drop latch 25 return to its locked position as the starting position occupies. If the lock drum 5 within or after the period the self-holding device is turned back to the starting position, so the locking stop can 27 the drop pawl 25 with respect to the spring force of the tension spring Turn back 26 so far that the locking stop 27 and the latch 25 automatically engage in the locking position, so that the starting position is restored and locked.

Fig. 5 shows an embodiment for a rotary mechanism 16 for driving the lock drums 5.5 ', 5 "of a throw-in lock 4, which acts as a three-chamber lock is executed. The arrangement of three lock drums is shown 5,5 ', 5 "with their lock chambers 6,6', 6", the axes of rotation 15 a form common axis 18 and which are independent of each other in their bearings 32 are rotatably mounted, which are attached to vertical support walls 31.

Each of the three lock drums 5.5 ', 5 "has a different volume Lock chamber 6, 6 ', 6 ". The gradation of the volumes of the lock chambers 6.6 ', 6 "can be, for example, 5 liters, 10 liters and 15 liters. Each lock chamber 6, 6 ', 6 "is a hand lever 10, 10', 10" with its initiator 30,30 ', 30 "assigned, with the respective hand lever 10,10', 10" of Rotating mechanism 16 for the selected lock drum 5.5 ', 5 "is actuated.

Depending on the choice of a hand lever 10, 10 ', 10 ", one of the lock drums activated, i.e. unlocked. This is triggered by operating the hand lever 10, 10 ', 10 "associated initiator 30, 30', 30". The input signal triggered thereby enables the microprocessor to register the used ones Lock chamber. Thus, the user of the multi-chamber lock can 4 Select the size of the lock chamber 6,6 ', 6 "depending on the requirements Volume of the garbage bag to be disposed comes closest.

The rotating mechanism 16 and the locking device 17 is for each of the Lock drums 5.5 ', 5 "are basically the same as those described above is. The drive shafts 21, 21 ', 21 "with the common axis of rotation 18 are stored in the bearings 33,34,35, the drive shafts 21,21 'as hollow shafts are formed so that the drive shaft 21 ", the drive shaft 21 'and both Drive shafts 21 ', 21 "penetrate the drive shaft 21 in terms of bearing particular advantage of this embodiment is that the hand lever 10, 10 ', 10 "of the drive shafts 21, 21', 21" is a combined group of juxtaposed hand levers form that are easily accessible and good are manageable.

Since the lock drum 5,5 ', 5 "after the filling process a rotary movement must travel with an angle of rotation of about 180 °, the angle of rotation of the Angular movement of the hand lever 10,10 ', 10 "but only be about 90 ° is the gear ratio between the respective driving pulley 22, 22 ', 22 "to the driven toothed belt pulley 23 approximately 2: 1.

The propellant transmission for generating a torque for actuating a Lock drum 5.5, ', 5 "can be used, for example, as a toothed, wedge, flat belt drive or be designed as a gear transmission.

The microprocessor's internal switching logic ensures that at all times only a lock drum can be operated.

The microprocessor can be battery operated, for example. For special Energy-saving operation of the microprocessor can be done outside of the Activation times can be operated in energy-saving mode. This can be special advantageously brought about by using transponder technology be, since the operation of the transponder technology on a very low Energy level based.

A transponder as an electronic key with a key code is special suitable, with this being assigned a user ID.

Transponder circuits have a reading module which is inside its Reading area recognizes the user coding of the electronic key, and in the case of the authorized user ID via a read contact a first input signal to activate the control electronics of the Microprocessor generated.

In principle, the user ID can also be encoded, for example Magnetic stripe card or by special key release.

The microprocessor contains an electronic, but not in the event of a power failure volatile memory. The user ID and the frequency are saved the use of the individual lock chambers related to the date and time. Via an interface of the microprocessor can be freely determined Time intervals, for example monthly, related to the usage data retrieved the user ID for billing waste disposal costs become.

Another advantage of a multi-chamber lock with different Volumes of the lock chamber is that by using the different lock chambers the scatter, i.e. the distribution of the trash bags within the waste container 2 is favorable and thus its degree of filling or improved the use of space.

6 to 35 illustrate a modified embodiment of a Throw-in lock according to the invention.

6 shows a housing 101 for housing a waste container 102 together with shown this. The housing 101 can be secured against displacement with the foundation plate 111 be connected. The waste container 102 is in the open Condition, in the interior 114 of the housing 101. The waste container 102 is equipped with rollers 112 and can in the interior 114 of the housing 10 can be moved in and out by opening the rear wall 113.

The top cover 103 of the housing 101 contains a throw-in lock 104, which can be operated from the front of the housing 101.

The throw-in lock 104 with its lock chamber 106 is in this Embodiment of the invention from a lock chamber housing 105 with a closure cap 108, which opens or blocks the filling opening 107, the closure cover 108 about a hinge axis via a handle 116 115 can be folded up. The lock chamber housing 105 is advantageous as Prefabricated unit and with the top cover 103 of the housing 101, which has a corresponding opening, screwed. The cap 108 is with a locking mechanism, not shown, advantageous the locking mechanism described above corresponding locking mechanism coupled and can only be opened by a user who has access authorization features. Such a locking mechanism can, for example also be designed as a magnet-operated locking mechanism.

The throw-in lock 104 comprises a trough trough 110, which is below the closure lid 108 translatable on a prismatic guide 117 is guided and forms a unit with the lock chamber housing 105.

In FIG. 7, the throw-in lock 104 is in the open, that is to say unlocked, state shown. A garbage bag 109 can thus pass through the filling opening 107 in the lock chamber 106 are inserted.

In Fig. 8, the lock chamber 106 is in the closed state with inserted Garbage bag 109 shown.

9 shows the throw-in lock 104 in the downwardly open state. This is brought about by operating the lock in such a way that one does not shown sliding mechanism, the trough 110 into a parking position is moved. This opens the passage opening 119, so that the Garbage bags 109 following the force of gravity into the interior of the waste container 102 can fall into it.

10 shows a section of the lock chamber 106 according to detail X in FIG. 6 in an enlarged view. The cross section of the lock chamber 106 is formed by the trough 110 with the trough wall 128, the lock chamber housing 105 and the cap 108. The cap 108 is hinged about the hinge axis 115 in the hinge bearing 125.

11 shows the section through the opened lock chamber 106 according to the detail Y in Fig. 7 in an enlarged view.

12 shows a longitudinal section through the lock chamber housing 105 in parallel and running half the distance to the prism guides 117. The housing 105 consists of the two end walls 120, the top cover 121, and the circumferential flange collar 122, with the attached to it Prismatic guides 117. These are, for example, cylindrical rod guides formed, which are clamped at their ends in bearing blocks 123 and are pinned by means of clamping sleeves 124, for example. Furthermore, the Lock chamber housing 105 halfway to end walls 120 over a fixed wall 118, this with the lock chamber housing 105 is a unit by a fixed connection. This connection can for example be produced by a welded connection.

FIG. 13 shows a view in the direction U in FIG. 12 and FIG. 14 shows a bottom view of the lock chamber housing 105 in the direction V in FIG. 12. FIG. 14 illustrates the parallel prism guides 117 that are in the pedestals 123 are pinned and stored. The circumferential flange collar 122 contains through holes 126 in the long sides for the passage of Screws, creating the lock chamber housing 105 with the top cover 103 of the housing 101 can be screwed.

Fig. 15 shows a section along the line A-A in Fig. 12 in an enlarged view. The partition 118 is designed so that it is partially between the upper Housing wall 105 and the partition wall 118 releases a gap opening 127, so that the trough trough 110 slide under this fixed partition 118 can. At the same time, the partition wall 118 prevents the trough trough 110 from being carried along of the garbage bag 109.

16 shows a cross section through a trough trough 110. The trough 110 consists of a trough wall 128, which with the surrounding guides 129 forms a unit, the surrounding guides 129 being designed in this way are that they grip the prism guides 117. The front ends the trough wall 128 are open on both sides.

Fig. 17 shows a section along the line C-C in Fig. 16 and Fig. 18 a lower View in the direction W of the trough 110 in FIG. 17.

19 illustrates a longitudinal section through a complete throw-in lock 104 with inserted garbage bag 109 with trough recess 110 parked on the right, i.e. to the right of the fixed wall 118, the cover 108 being closed is. The displaceable wall 130 serves as a plunger and is located on the right side in the parking position. Is also in a parking position the displaceable wall 130 'as a plunger in the left-hand parking position the trough trough 110. Both closure covers 108, 108 'are closed and locked. The trough 110 and the movable walls 130, 130 'become common on the same prismatic guide 117 guided translationally.

Fig. 20 shows a section along the line D-D in Fig. 19 with inserted garbage bag 109 and FIG. 21 a view of the insertion lock from below in the direction V in Fig. 19.

22 shows a longitudinal section through a complete throw-in lock 104 with inserted garbage bag 109 in the compressed state, the trough trough 110 and the displaceable wall 130 having been moved as pressing pistons by the displacement path S ₁ in the direction of the fixed wall 118, so that the garbage bag 109 has experienced a compression and thus a reduction in its volume. The cause of the upsetting is the pressing force (P) as the action force, which is opposed by the reaction force (-P) which emanates from the fixed wall 118.

The original chamber volume of the lock chamber 106 has now been reduced to the remaining lock chamber volume 106 '. The distance (ΔS) multiplied by the cross-section of the lock chamber represents the remaining chamber volume, which at the same time forms the chamber volume to be billed for the user. The reduction in the chamber volume is brought about by displacing the movable wall 130 as a plunger by the displacement path (S ₁ ). The displacement path (S ₁ ) is reported by a displacement sensor 132 to a microprocessor, which stores it as a value. The force (P) with which the displaceable wall 130 acts on the garbage bag 109 is detected by means of a sensor, for example designed as a load cell, and is also reported to the microprocessor. If the preselected setpoint value which is stored in the microprocessor is reached, then the sliding movement of the sliding wall 130 stopped as a plunger.

Fig. 23 shows a section along the line D-D in Fig. 17 and Fig. 24 is a view from below in the direction V in FIG. 22.

FIG. 25 shows a longitudinal section through the throw-in lock 104 analogous to FIG. 22, the displaceable wall 130 remaining in its position with the displacement path (F ₁ ) according to FIG. 19. In the meantime, the trough trough 110 has covered a further displacement path and overall the displacement path (S ₂ ) and has thus simultaneously reached its left parking position. It is thus on the left side of the movable wall 130 'as a plunger.

By transporting the trough 110 in the direction of F became the garbage bag the floor, which is formed by the trough wall 128, removed so that the passage opening 119 is released.

Fig. 26 shows a section along the line D-D in Fig. 25 and Fig. 27 is a view in direction V in Fig. 25 from below.

29 shows a longitudinal section through the insertion lock 104, whereby the trough 110 is in the left parking position and the sliding Wall 130 as a plunger is again on its right side in its starting position located. As a result, the clamping force P of the garbage bag 109 is eliminated, so that the garbage bag 109 follows the passage opening 126 by gravity could happen and is inside the waste container 102.

Fig. 29 shows a section along the line D-D in Fig. 28 and Fig. 30 is a view in the direction V in Fig. 28 from below.

FIG. 31 now shows the starting position for the repetition analogously to FIG. 28 of the filling process on the left. In this starting position the lock chamber 106 below the cover 108 '. Both Caps 108,108 'are locked in this park position, which is a microprocessor is reported by the sensors 131, 131 'as input signals. The respective parking position of the trough depression 110 can be determined via the sensors 133, 133 ' also be reported to the microprocessor as an input signal, so that the An LED display lets users identify which side the feed lock can be released for use. The moveable Walls 130, 130 'are each equipped with a sensor as a displacement sensor 132.132 '.

32 shows a longitudinal section through a throw-in lock 104, wherein 19, a garbage bag 109 is located in the lock chamber 106 'as in FIG. 19. The emptying process can be carried out in the same order as in the 19 to 30 shown take place, the direction of movement of the trough 110 then follows the direction arrow with the direction of movement F '.

In principle, it is also possible that the movable walls 130, 130 'with the To couple trough trough 110 on both sides, the trough trough 110 and the movable Walls 130, 130 'are guided by the same prism guide 117. For this it is necessary that a relative movement between trough trough 110 and the respective movable wall 130, 130 'is possible. This coupling can for example by tension springs or by controlled pneumatic cylinders or be realized by a combination of tension springs and pneumatic cylinders.

Fig. 33 shows a longitudinal section through a throw-in lock 104 with left and on the right side of the trough trough 110 coupled to this sliding walls 130.130 '.

FIG. 34 shows an enlarged illustration of the trough depression 110 according to FIG. 33 with a coupling, which is generated by the tension springs 134, 134 '. The tension springs 134, 134 'are on the one hand on both sides of the trough trough 110 in the attachment points 135.135 'and the other on the movable walls 130.130' in the anchor points 136, 136 'struck and pretensioned so that the movable Walls 130, 130 'with the prestressed force of the tension springs 134, 134 'can be pressed against the front openings of the trough trough 110.

FIG. 35 finally shows the trough trough 110 according to FIG. 34 with the wall 130 displaced relative to the trough trough 110, so that this opens a passage opening 119 downward, for example through the displacement path (S ₃ ). This presupposes that the displaceable wall 130 can be displaced by an actuating element, for example a pneumatic cylinder, against the spring force of the tension spring 134, so that the passage opening 119 is continuously but limited by the trough depression 110 during the displacement movement (F or F ') can increase the stroke of the pneumatic cylinder. Thus, the passage cross section of the passage opening 119 can be brought about in a controlled manner, which is required in order, for example, to drop a garbage bag 109 into the waste container 2.

FIGS. 36 and 37 show a further embodiment in analogy to FIGS. 34 and 35 a trough 110 with the sliding wall 130 with a Coupling by leaf springs 137. A leaf spring 137 is designed so that it a bend 138 at one end and screw connections at the other end 139 for attachment to the trough trough 110. The crank 138 is For example, V-shaped, so that the crank 138 is on both sides Result in bevels. The offset 138 engages behind in the direction of displacement the sliding wall 130 on it and thereby creates during the displacement movement F of the trough 110 a positive and positive connection between the leaf spring 137 and the slidable wall 130.

The section modulus of the leaf spring is dimensioned so that the Leaf spring 137 against evasion, i.e. against their deformation due to bending, is opposed to a clamping force counteracting the deformation, so that of this leaf spring 137 a towing force to take the displaceable Wall 130, 130 'goes out.

Due to the drive of the trough trough 110 to generate the displacement movement F is generated a drag force that is sufficient to trough trough 110 and sliding wall 130 can be moved synchronously for as long as until the sliding wall 130 meets the garbage bag 109 and this may be slightly compressed. Exceeds that of leaf spring 137 drag force which can be transmitted to the displaceable wall 130, the leaf spring gives way by deformation as a result of their resilient behavior, so that the Slidable wall 130 is uncoupled from the trough 110 and the movement the sliding wall 130 is thereby ended. 37 is the decoupled state shown.

For example, the transport movement of the trough 110 and the displaceable Wall 130 brought about by the drive by means of an electric motor, for example through the combination of the drive elements, pinion - Rack or drive spindle - spindle nut or drive wheel - drive belt, so increases during the impact of the sliding wall 130 on the Obstacle garbage, for example a garbage bag 109, the required drive torque on the output shaft of the electric motor, which at the same time with an increase in its current consumption is connected. By a given The current consumption threshold is exceeded when this current consumption is exceeded this event as the beginning of the standstill of the sliding wall 130 evaluated, which is supplied to the microprocessor as an input signal. In Connection with the displacement sensor 132, 132 can thus be used Waste disposal volume can be determined and saved. The Travel sensor 132, 132 'can also be designed, for example, as an incremental encoder be coupled to the output shaft of the electric motor.

An alternative embodiment of a towing mechanism for leaf spring design 36 or FIG. 37 can also by a magnetic contact between the trough trough 110 and the displaceable wall 130, 130 ' the drag force represents the magnetic holding force. After exceeding the magnetic holding force, the towing force is interrupted, like already described above. The magnetic holding force can be optional generated either by a permanent magnet or by an electromagnet become.

38 shows the basic structure of a microprocessor control 149 an embodiment of an actuator 147 of a garbage throw with a spindle drive. The system structure of the microprocessor control is structurally essentially characterized by the functional units User interface 150, measuring control electronics (MSR electronics or microprocessor) 151, parameter calculation 152, user data memory 153 and external interface 154.

The sensors of the microprocessor control 149 consist of an incremental encoder 144 as a displacement transducer, for example equipped with an impulse sensor Hall sensor, a current consumption sensor 148 and the end position sensors 159; 159 '. The reference sensor is used to reference the displacement transducer 160, which is assigned to a defined starting position of the trough depression 110 is. The reference sensor 160 is the MSR electronics 151 as an input signal E 160 is assigned.

The drive spindle serves as the drive element of the actuating device 147 140, for example designed as a ball screw, which is driven by an electric motor 143 is powered by the battery 155 as a power supply. The drive spindle 140 is in their spindle bearings 141, which on the lock chamber housing 105 are supported, stored. The drive shaft 145 of the electric motor 143 and the drive spindle 140 are rotationally fixed by means of a coupling 146 coupled. The housing of the electric motor 143 is also on the lock chamber housing 105 supported thereby also the reaction torque of the drive torque is supported against the lock chamber housing 105.

The trough trough 110 is connected to the drive spindle by means of a spindle nut 142 140 slidably coupled. For the sake of clarity, the Drive spindle 140 shown below the trough trough 110, the drive spindle 140 because of the falling garbage outside the throw-in area parallel to the movement F of the trough trough 110 must be placed.

The user interface 150 consists of a reading module for recognizing the user authorization, for example designed as an electronic key according to the transponder technology. With the transponder 157 as electronic With appropriate user identification, the throw-in lock 104 can be key activated, i.e. unlocked for use so that one of the caps 108,108 'unlocked depending on the parking position of the trough trough 110 becomes. The end position sensors 159, 159 'are the MSR electronics 151 as input signals E159, E159 'assigned.

After activation by the authorized user, the garbage can, for example a garbage bag 109, inserted into the lock chamber 106, 106 ' become. The closing cover 108, 108 'is then closed by hand. This closing process is dependent on that of the respective end position of the trough depression 110 assigned end position sensor 159, 159 'is detected, as a result of which the addressed End position sensor 159, 159 'of the MSR electronics 149 by an input signal E159, E159 'announces.

As a result, the MSR electronics 149 generates an output signal A156 or A156 ', which defines the direction of rotation of the electric motor 143 and this thereby being set in motion. This also makes the shifting movement the trough trough 110 including the respectively associated displaceable Wall 130, 130 'started.

The drive shaft of the electric motor 143 stands with an incremental encoder 144 in operative connection, so that the incremental encoder 144 as a displacement sensor for the current determination of the location coordinate along the displacement path in relation acts on the reference point of the trough trough 110. The incremental encoder pulses 144 are available as input signal E 144 at the MSR electronics 151, so that the parameter calculation 152 the current location coordinate of the Trough depression 110 with respect to the reference point of the reference sensor 160 during of the path of the trough 110 is known.

The circuit of the electric motor 143 is with a current consumption sensor 148 equipped, which detects the current power consumption. The current collector generates the input signal E148 on the MCR electronics.

In the event of a significant increase in power consumption through the formation of a Peaks at the moment the slidable wall 130 hits the obstacle garbage, for example the inserted garbage bag 109, becomes this Event from the microprocessor controller 149 as a limit of the displaceable Wall 130 scored and registered.

Since the path coordinate of the trough depression during the arrival of this event is also known as input signal E144, can by the parameter calculation 152, assigned to the respective user, the claimed Waste disposal volume is stored in the user data memory 153 become .

The user data is stored in a RAM memory. This can for example, be designed as an EPROM memory or as a chip card (Data recording card). Alternatively, the data memory can also be used as RAM memory be formed, the stored data via an external interface 154 can be transferred to external data storage. This can for example also by radio transmission using a transmitter 158.

Another advantage of the invention is that the systematic Recording and storage of the waste disposal volume used by adding up the waste disposal volume, the degree of filling of the waste container can be determined continuously. This makes a separate one unnecessary Level control, especially considering statistical Evaluations of an almost completely filled waste container is recognized in good time, which causes possible blockages and thus malfunctions the operational process can be prevented by the access authorization is blocked in time. An indication of this condition can also be made in good time Clues. This can be sent to a waste disposal company via a radio link be communicated, causing the waste container to be emptied can.

Conversely, it can also be possible to determine the degree of filling of the waste containers 2.102 to be queried by radio.

Claims (33)

1. Loading lock for precincts (101) for housing refuse collecting bins (102), with a lock compartment (106) which may shift from a loading position to a depleting position, which may be loaded by means of a loading opening with waste, for example refuse bags, and may be depleted into the refuse collecting bin (102), the above mentioned loading lock (104) having only one lock compartment (106), characterized in that the lock compartment (106) may change its volume.
2. Loading lock according to claim 1, characterized in that the lock compartment (106) may gradually and automatically adjust its volume to the volume of the waste to be removed.
3. Loading lock according to claim 1 or 2, characterized in that the lock compartment (106) has at least a mobile wall (130, 130') which may shift with respect to the other confining walls of the lock compartment (106) over a shifting distance (S1).
4. Loading lock according to claim 3, characterized in that the mobile wall (130, 130') is formed as a pressing piston, by means of which the refuse may be pressed and in this case deformed with a preset pressing force (P).
5. Loading lock according to claim 3 or 4, characterized in that the shifting distance (S1) of the mobile wall (130) may be determined and stored up by means of a shifting recorder (132).
6. Loading lock according to any one of the claims from 3 to 5, characterized in that a rigid wall (118) built as a component part of the box (105) of the lock compartment is attached to the mobile wall (130, 130') which has the role of a counter support to absorb the pressing force (P).
7. Loading lock according to any one of the preceding claims, characterized in that some of the confining walls of the lock compartment (106) are formed as a chute shaped tub (110) which may be shifted by means of a parallel displacement movement alongside a guideway built on a component part of the box (105) of the lock compartment.
8. Loading lock according to any one of the claims from 3 to 7, characterized in that an actuating appliance (147), both of the mobile wall (130, 130') and the chute shaped tub (110), may be directly and manually actuated.
9. Loading lock according to any one of the claims from 3 to 7, characterized in that an actuating appliance (147), both of the mobile wall (130, 130') and the chute shaped tub (110), is automatically driven by means of an auxiliary power.
10. Loading lock according to any one of the claims from 7 to 9, characterized in that the chute shaped tub (110), as a result of its mobility, may be guided over the both parts of a rigid wall (118) to stoppage positions which are the loading positions of the chute shaped tub (110), where for every one of its stoppage positions the loading lock (104) has a loading opening (107, 107') which may be closed and fixed by means of a closing lid (108, 108').
11. Loading lock according to claim 10, characterized in that it has a LED display which is optically letting the user know the corresponding stoppage position and therefore the loading opening (107, 107') available for use.
12. Loading lock according to any one of the preceding claims, characterized in that the loading lock (104) has a microprocessor actuated fixing appliance which may be relieved by means of a machine read data carrier to allow its free use, where the user's specific data and the volume of the refuse he threw in the lock compartment at that given hour and day may be stored up and later retrieved by a microprocessor actuated appliance (149).
13. Loading lock according to claim 12, characterized in that the fixing appliance may be relieved by a machine read user's recognition and/or approval in order to allow the free use of the loading lock (104).
14. Loading lock according to claim 12 or 13, characterized in that the loading lock (104) has a microprocessor actuated appliance (149) which may perceive, recognize and store up the user's recognition and approval to generate an output signal to be later used in order to relieve the fixing appliance of the loading lock (104) if the user's approval has been established.
15. Loading lock according to any one of the claims from 12 to 14, characterized in that the lock compartment (106) is closed by means of the closing lids (108, 108') and has a sensor (131, 131') which after the opening and the immediate closing of one of the closing lids (108, 108') generates an input signal for the microprocessor actuated appliance (149) whereby an output signal will be later generated.
16. Loading lock according to any one of the claims from 12 to 15, characterized in that the mobile walls (130, 130') have shifting recorders (132, 132', 144) so that their measuring data use the microprocessor actuated appliance (149) to establish the volume taken in the lock compartment, where this result may be stored up, there being the possibility to be later retrieved.
17. Loading lock according to any one of the claims from 12 to 16, characterized in that the microprocessor actuated appliance (149) has a slot to carry the user's stored up data on, a mechanically read external data carrier.
18. Loading lock according to any one of the claims from 11 to 17, characterized in that in order to allow the free use there is a transponder technology based electronic key, where the transponder has a key code which may be perceived and read by the receiving stationary electronic part of the transponder's reading module, and where the reading module, if the user's approval has been established, actuates by means of a: Read contact the actuating electronic of the microprocessor actuated appliance (149).
19. Loading lock according to claim 9, characterized in that the actuating appliance of the chute shaped tub (110) consists of a driving device made of an electromotor and a rack fitted pinion.
20. Loading lock according to claim 9, characterized in that the actuating appliance of the chute shaped tub (110) consists of a driving device made of an electromotor and a guide bar nut fitted driving shaft.
21. Loading lock according to claim 9, characterized in that the actuating appliance of the chute shaped tub (110) consists of a driving device made of an electromotor and a belt fitted driving sheave.
22. Loading lock according to any one of the claims from 9 to 20, characterized in that the actuating appliance of the chute shaped tube (110) driving motor's axle is wired up to a shifting recorder.
23. Loading lock according to any one of the claims from 19 to 22, characterized in that the power dissipation of the driving motor used as an electromotor (143) may be sensorially perceived by means of a power dissipation sensor which may perceive the hitting of the mobile wall (130, 130') either by the refuse or the refuse bags (109) as a power increase which will be conveyed as an input signal (E 148) to a microprocessor actuated appliance (149), the microprocessor actuated appliance (149) using this input signal (E 148) in regard of another input signal (E 144) generated by a shifting recorder, for example designed as an increment measuring sensitive element (144) to establish the volume taken in the lock compartment.
24. Loading lock according to any one of the claims from 7 to 23, characterized in that the chute shaped tub (110) and the mobile wall (130, 130') may be connected by means of some spring elements.
25. Loading lock according to claim 24, characterized in that the spring elements are made as plate springs (137).
26. Loading lock according to any one of the claims from 7 to 23, characterized in that the chute shaped tub (110) and the mobile wall (130, 130') may be connected by means of magnetic field strength.
27. Loading lock according to any one of the preceding claims, characterized in that the data carrying from the precinct of the stationary refuse bin (1, 101) for supplementary processing on external data reading devices may take place by means of an electronic card (data carrier card).
28. Loading lock according to any one of the claims from 1 to 25, characterized in that the data carrying from the precinct of the stationary refuse bin (1, 101) for supplementary processing on external data reading devices may take place by means of radio transmission.
29. Loading lock according to any one of the preceding claims, characterized in that the filling level of a refuse collecting bin (2, 102) will be established by adding up the real volumes of the refuse thrown by the users.
30. Loading lock according to claim 29, characterized in that the loading lock carries out the filling by means of a blocking device which blocks the loading lock to prevent its use as soon as a final preset filling level, which signals the filling, is reached.
31. Loading lock according to claim 30, characterized in that the loading lock carries out the filling by means of an optical signaling device which indicates the reaching of the final filling level, signaling the filling.
32. Loading lock according to claim 31, characterized in that the loading lock carries out the filling by means of an optical signaling device which indicates the reaching of the final filling level, signaling the filling by means of a radio signal.
33. Loading lock according to claim 29, characterized in that the reaching of the filling level of a refuse collecting bin (2, 202) may be checked up by means of radio waves.

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