DE3301045C2 - - Google Patents

Description

The invention relates to an automatic feeding device, especially for aquariums, which in the preamble of Claim 1 defined Art.

A known automatic feeding device of this type (DE-OS 29 27 960) has as a drive device for the drum an electric motor connected to the Household network is to be connected and is powered by the network. The electric drive motor consists of, for example Synchronous motor. Between its drive shaft and that driven by it Storage drum sits a clutch with gears, Cutouts and cams, which is complex and complicated. The drive motor is powered by a special timer Form controlled by an electrical clockwork and switches accordingly in and out. The clockwork drives one by means of settable Programmable program disk on. To the selected one The set program cams actuate the time electrical switch, which then drives the electric motor energizes and turns on. The storage drum is thereby initially not yet driven, but only when another program cam engages in the clutch transmission means. Such a feeding device has proven itself,  is very complicated, relatively large, difficult and unwieldy. The main disadvantage is the high price, which results not least from the fact that for the program work a special timekeeping is necessary and for temporary Rotary drive of the storage drum switched on according to the program a special, mains-dependent electric motor. The latter, that is powered by a power cord is impaired because of this cable also the free handling of the device. The Power cord often interferes and is free to position and movement of the feeding device in the way. Furthermore pose problems of electrical safety. These can only be done with great effort and considerable Master costs. So the feeding device z. B. to be waterproof encapsulated to provide protection offer if the device when handling z. B. accidentally should fall into the aquarium tank. Another The disadvantage arises from the fact that this also known Feeding device during a relatively short Phase is fed, which is a desired optimal feed utilization opposes and also not the feed conditions in nature. So would be B. to strive to feed the daily amount of feed so slowly that all fish receive their feed quantity in succession and that no leftover food remains and rots somewhere.

The invention has for its object an automatic Feeding device of the type mentioned create that is small, light and compact, above all is inexpensive, which is also inexpensive to use and free positioning possibilities open up everywhere, a high grade Guaranteed electrical safety and everything makes it possible with simple, cheap means that over fed a certain amount of time and slowly fed it is supplied without abundance and so that in particular in aquariums all fish side by side their food quantity preserved and no food residues remain anywhere and spoil.

The task is with an automatic feeding device of the type mentioned according to the invention the features in the characterizing part of claim 1 solved. Further advantageous features emerge from the claims 2-5.

The automatic feeding device according to the invention has the following advantages. On the one hand, it needs one Drive unit, which is also designed as a clockwork drive with the individual features of the invention is particularly small, light, compact and inexpensive. This clockwork drive is not only used as needed Rotary drive of the storage drum used as a drive unit, but also to control the program wheel, through which the normally disengaged clutch closes the programmed feeding times. The Invention makes the special properties of a Movement drive in a strange and surprising way take advantage of the fact that a clockwork drive an inner shaft rotating at 1 revolution per hour, the so-called minute drive tube and also an outer one Hollow shaft that rotates with 1 revolution in 24 hours and is referred to as a so-called 24-drive tube. Clockwork drives inherently have an extremely small drive torque, that for the normal drive of the minute hand and hour hand is fully sufficient. Therefore are such clockwork drives when certain drive powers apparently needed to be discarded as unsuitable. The invention goes beyond prejudice whereby a drive device in a surprisingly simple manner both for temporarily rotating the storage drum as well as the timekeeping drive the program wheel is created. Since clockwork drives as practically complete units are traded and traded in large quantities are produced, they are relative inexpensive. The invention includes a mechanical Clockwork drive, instead of an electrical one, e.g. B. one Clockwork drive, which is designed as a long-term drive  and Z. B. driven by a spring motor containing becomes. An electrical, quartz-controlled is particularly preferred Movement drive used. This has the advantage a low power consumption, so that a single Baby cell as a battery is already sufficient. Thereby, that the feeding device is off-grid achieved significant advantages in use. For one, offers the feeding device has a high level of electrical Security even when the device is in the water should fall or otherwise come into contact with water should come. On the other hand, the handling is extraordinary easy. The device is trouble-free without a power cord can be placed at any desired position can be recorded at any time and moved to another location. Furthermore, a high degree of operational security has been achieved and practically no maintenance is required. Advantageous it is also noticeable that now all prerequisites for this are created, the feeding device also a decorative and at the same time to give it a striking appearance. Another major advantage is that due to the clockwork drive is fed via a predetermined longer period of time can take place. So can e.g. B. the feeding process over a period of 15-20 Minutes. This has the advantage of a good one Utilization of the feed. Furthermore, this comes from the natural Process very close. This allows the feed to be fed slowly be that all the fish in an aquarium are successively get their food quantum, at the same time none Leftover food remains and rots. An oversupply is thus avoided.

Further advantageous features emerge from the claims 6-35. The advantage is that the effort for gear Medium is extremely small. Particularly advantageous is the loop spring clutch than normal disengaged, i.e. not drifting clutch. Here, low stopping forces are sufficient to secure the loop spring clutch to be looped and thus any  Remove drive coupling. In the disengaged state Clutch therefore have no friction or braking forces on the drive shaft, d. H. on the minute drive tube of the Clockwork drive. So this can run through without problems, without being damaged by braking torques to take. The locking device in the form of the spring lever, the in a simple way from the programmable cams of the Unlocking the program wheel for a short time also requires no big effort. The spring lever can be used as Manufacture one-piece plastic molded part inexpensively, just like all the other parts, you can see the die Loop coil clutch forming cylindrical coil spring from. This also has a cost-reducing effect. The special one Design of the program wheel and the program cams leads as radially insertable pins from the outside to make the device compact and small can and still programming from the outside It is possible to insert the pins. No one is required for this special expertise. Any lids that do that Completely lock the housing, do not need to be replaced to become. The feeding device is therefore special easy to use.

Further details and advantages result from the following description.

The invention is based on one in the Drawings shown embodiment of a automatic feeding device, especially for Aquariums, explained in more detail. Show it

Fig. 1, 2 and 3 is a schematic front view and plan view and side view of the apparatus,

Fig. 4 is a schematic, exploded perspective view of the device with a cover removed element,

Fig. 5 is a schematic, perspective view of the lifted lid member,

Fig. 6 is a schematic, partial perspective view of a housing wall with the spring lever and the intermediate sleeve,

Fig. 7 is a schematic, perspective view of parts of the spring lever and the loop spring coupling, the latter in the disengaged, not by the driving state,

Fig. 8 is a schematic, enlarged sectional view of details of the driving means of the device in a disengaged, not by driving the loop spring clutch,

Fig. 9 is a schematic end view in the direction of arrow IX in Fig. 8, in the disengaged and not by driving the loop spring clutch,

Fig. 10 is a plan view of the part in Fig. 9,

Fig. 11 is a perspective, schematic view of a removable closure lid of the storage drum,

Fig. 12 is an end view of the cap in Fig. 11,

Fig. 13 is a section along the line XIII-XIII in Fig. 12.

In the drawings is an automatic feeding device shown especially for aquariums that the serving of pourable feed in portions.

The device has a multi-part housing 10 , in particular made of plastic, which consists of a square, approximately trough-shaped bottom part 11 , a hood 12 and a cover element 13 and three housing walls 14, 15 and 16 . At the right end in FIG. 4, the bottom part contains a battery compartment 17 with an indicated battery 18 in the lower region. The battery compartment 17 is closed by a removable cover 19 which is detachably held on the bottom part 11 on the one hand and on the hood 12 on the other hand and can be removed for changing the battery 18 . In the closed state according to FIGS. 1-3, the hood 12 placed on the bottom part 11 from above connects practically seamlessly to the side walls 20, 21 of the bottom part 10 , which is sealed at the right end area by the hood 12 and the cover 19 . The hood 12 and the cover 19 are detachably attached and / or clipped on. For clipping, spring tongues 22 designed on both sides with locking bolts at the ends are used in a conventional manner. The cover element 13 which is placed on the base part 11 from above also closes practically seamlessly on the hood 12 and the side walls 20, 21 and the left end wall 23 of the base part 11 and closes it off like a coffin cover. The interior of the base part 11 is then vented to the outside only via two lateral ventilation openings 24 and 25, respectively , which are contained in the side walls 20, 21 .

At this point, the bottom wall of the bottom part 11 contains an opening 26 which extends in the transverse direction from one side wall 20 to the other side wall 21 .

In the bottom part 11 , a storage drum 27 , into which feed is filled, is held rotatably about a lying axis 28 . The storage drum 27 carries at the left in Fig. 4 a removable cover 29 , which is attached and in its cylinder wall at the same location as the opening 26 has a feed discharge opening 30 through which the feed contained in the interior of the storage drum 27 exit in a certain rotational position and then can fall down through the opening 26 . At the left end in FIG. 4, the closure cover 29 carries a bearing pin 31 which is rotatably mounted on the end wall 23 in a half-eye 32 which is open at the top for rotary mounting about the axis 28 . The supply drum 27 is inserted therein from above.

The drive of the supply drum 27 is a drive means 33, wherein between the drive shaft 34 and the supply drum 35 is disposed a clutch 27 which is designed as a loop spring coupling. The clutch 35 can be engaged and disengaged. It is normally disengaged, in which case the storage drum 27 is not driven. If, on the other hand, the clutch 35 is engaged, the supply drum 27 is driven in rotation by the drive device 33 in the direction of the arrow 36 . The clutch 35 can be engaged by means of programmable cams 37 of a program wheel 38 which is driven in a time-keeping manner.

In a special design, the drive device 33 consists of an electric clockwork drive 39 , which is independent of the network and quartz-controlled and is fed by the battery 18 . This clockwork drive 39 is known from battery-operated, quartz-controlled clocks and is used completely as a block, schematically indicated in FIG. 4, which sits between the two housing walls 15 and 16 . Despite the known extremely small drive torque that such a clockwork drive 39 can generate, this is sufficient for driving the storage drum 27 due to its special design. The drive shaft 34 is formed by the so-called minute drive tube of the clockwork drive 39 , which makes 1 revolution per hour and is guided as an inner shaft through a hollow shaft 40 . The hollow shaft 40 represents the so-called 24-hour drive tube driven by the clockwork drive 39 , which makes 1 revolution within 24 hours and normally drives the hour hand in watches, while the minute drive tube, i.e. the drive shaft 34 , drives the minute hand in watches. By means of the clockwork drive 39 , the program wheel 38 is also driven at the same time, namely in that the program wheel 38 is seated directly on the hollow shaft 40 . The hollow shaft 40 thus serves to control, while the inner drive shaft 34 serves to drive the storage drum 27 .

The clockwork drive 39 with program wheel 38 and clutch 35 is located on the right in FIG. 4 and connects there to the end of the storage drum 27 , the entire unit being arranged coaxially with the storage drum 27 . The entire unit is combined to form an overall block that is axially assembled and held together, this overall block as a unit being able to be pushed into the bottom part 11 of the housing 10 from above and pulled out in opposite directions, as for a part, namely the housing wall 14 , is shown in Fig. 4. The individual housing walls 14, 15 and 16 are held together axially by pins and are to be pulled out as a package.

At the right end in FIGS. 4 and 8, the storage drum 27 contains an axial depression 41 with which it is centered and supported on a centering ring 42 of the housing wall 14 . An axle journal 43 with a radial web 44 sits on the supply drum 27 within the depression 41 . The journal 43 is received in an intermediate sleeve 45 which is coaxial therewith. This contains an axial recess 46 , in which the radial web 44 engages, so that there is a coupling in the circumferential direction. The intermediate sleeve 45 is rotatable in the housing wall 14 and is held axially displaceably. For this purpose, the intermediate sleeve 45 lies axially with a flange 47 on the right side of the housing wall 14 in FIG. 8. On the other axial side there is a ring 48 , which engages with radial lugs in recesses 49 of the intermediate sleeve 45 from the outside and rests axially on the centering ring 42 . The intermediate sleeve 45 is integral with a sleeve portion 50 so that the movement drive 39 in front of him.

The drive shaft 34 , that is, the so-called minute drive tube, has a threaded shoulder 51 at the free, projecting end, which is flattened on both sides at 52 . A small drum 53 is placed on the threaded shoulder 51 , which has suitable flats 54 and is fixed by means of a nut 55 . The drum 53 is part of the clutch 35 . It is positively connected to the drive shaft 34 via the flats 52 and 54, and thus rotates together with the latter.

The coupling 35 has a cylindrical coil spring 56 with an approximately radially directed short spring end 57 on one and a long spring end 58 on the other axial end. The coil spring 56 wraps around the drum 53 in such a way that in the normal state there is a certain radial clamping force which is sufficient to drive a torque from the drum 53 to the coil spring 56 and from the short spring end 57 to the intermediate sleeve 45 and the supply drum coupled to it 27 to be transferred. The short spring end 57 , the z. B. runs approximately radially, engages positively in an open at the right end axial slot 59 on the sleeve portion 50 of the intermediate sleeve 45th So if the longer spring end 58 finds no resistance when driving in the direction of the arrow 36 ( FIGS. 7-10) and can rotate with it, the helical spring 56 contracts due to the rotating drum 53 , so that it extends over the short spring end 57 in the axial slot 59 takes the intermediate sleeve 45 . The storage drum 27 is driven.

It goes without saying that a force acting against the drive direction according to arrow 36 and holding the longer spring end 58 leads to the fact that the coil spring 56 is now turned in the opposite direction instead of being contracted, increasing the inside diameter. This releases the pinch on the small drum 53 . This then runs through empty, without friction between the drum 53 and the coil spring 56 and thus a loss of friction would still have to be covered on the drive side in this area.

The long spring end 58 is z. B. also radially or tangentially. It interacts with a special locking device 60 which can be controlled by the program wheel 38 . The locking device 60 has a spring lever 61 which is held on the right side of the housing wall 14 in FIGS. 6-8. The spring lever 61 has an approximately circular central part 62 through which the intermediate sleeve 45 with the sleeve section 50 can pass unhindered. A lower tab 63 and upper tab 64 are in one piece with the central part 62 , the spring lever 61 being fixed at approximately 65 at the housing wall 14 in the region of the lower end of the lower tab 63 . The lower tab 63 is cranked, so that from there the spring lever 61 extends at a free axial distance from the housing wall 14 and can be deflected towards it in the direction of arrow 66 ( FIG. 8). At the level of the upper tab 64 , the housing wall 14 carries a guide web 67 with an aperture 68 through which the tab 64 extends upward. The guide web 67 is provided on its axially projecting, right-hand edge in FIG. 10 with a control surface 69 which runs in an arc shape on both sides. The upper tab 64 is extended upwards as a handle and passed through a slot-shaped housing opening 70 in the hood 12 to the outside, so that one can engage the spring lever 61 there by hand. A peripheral portion of the program wheel 38 also protrudes outward through the housing opening 70 , so that the program wheel 38 can be programmed there from the outside without the hood 12 having to be removed.

The spring lever 61 carries on the upper tab 64 a one-piece cam 71 which projects towards the program wheel 38 and is approximately arrow-shaped. The cam 71 is the control cam which, when the program wheel 38 rotates (1 revolution per 24 hours), touches the respectively set program cam 37 and is then pressed to the left in FIG. 8 according to arrow 66 . The spring lever 61 thus springs out in the direction of the housing wall 14 .

The spring lever 61 also carries a locking hook 72 below the cam 71 and where the middle part 62 merges into the upper tab 64 , which is also integral therewith. This is in the normal position of the spring lever 61 ( Fig. 8-10), i.e. when no program cam 37 has acted on the cam 71 , up to the longer spring end 58 and brings the braking force acting in the opposite direction to the drive direction according to arrow 36 to the spring end 58 on. The clutch 35 is thus disengaged in this state. It does not separate or drive through. If, on the other hand, the spring clip 61 is pressed to the left against the spring force in the direction of arrow 66 ( FIG. 8) by a program cam 37 , as described above, the locking hook 72 releases the longer spring end 58 . The spring end 58 snaps past the locking hook 72 resiliently in the direction of arrow 36 . The coil spring 56 can now make one revolution. Immediately after passing the spring end 58 , the spring lever 61 resiliently returns to the starting position ( FIG. 7-10) as soon as the program cam 37 no longer acts on the cam 71 .

By releasing the longer spring end 58 , the drive shaft 34 drives the helical spring 56 , which is tightened on the drum 53, and thus the spring end 57 via the small drum 53 . The small drum 53 is thus driven through to the intermediate sleeve 45 and the storage drum 27 . This now makes 1 revolution per hour, the dimensioning of the feed discharge opening 30 being chosen approximately such that the feed discharge opening 30 reaches the area of the opening 26 after about 20 minutes, then the feed discharge and the storage drum take place over a further 20 minutes 27 then runs for another 20 minutes until after 1 hour the longer spring end 58 strikes the locking hook 72 again. The coil spring 56 is then turned up against its bias so that its clamping on the small drum 53 is released . The latter becomes free and rotates freely relative to the now fixed coil spring 56 without there being any frictional losses in between.

The guide web 67 holds the spring lever 61 in position, the curved control surface 69 being of particular importance. When the longer spring end 58 has become free and revolves, it leads this as soon as it reaches the region of the guide web 67 at the end of the revolution. The control surface 69 guides the spring end 58 in such a way that it definitely reaches the desired position shown in FIG. 10. The control surface 69 thus serves this security. The locking hook 72 does not extend very far transversely in front of the spring end 58 . This is due to the following security considerations. If the supply drum 27 is rotated in the opposite direction to the arrow direction 36 , this has no influence. Then the spring end 58 moves in the opposite direction to the arrow 36 away from the locking hook 72 . If the spring end 58 reaches the other side of the locking hook 72 during this opposite rotation, it can slide over an inclined surface 73 provided on the back into the position according to FIG. 10. If, on the other hand, the supply drum 27 , starting from the disengaged clutch state according to FIGS. 8-10, is rotated in the drive direction according to arrow 36 , an auxiliary cam 74 with an inclined surface 75 causes the spring end 58 to be forced to the right via the inclined surface 75 in FIG. 10, until it can pass the locking hook 72 . The auxiliary cam 74 is thus intended to prevent damage to the spring end 58 or other damage in the case mentioned. The auxiliary cam 74 is an integral part of the intermediate sleeve 45 . It is located at a greater radial distance than the sleeve section 50 and protrudes at the longer spring end 58 .

From the above description it is clear that the clutch 35 engages on the one hand - via the intermediate sleeve 45 - on the storage drum 27 in the circumferential direction, both in the disengaged, non-driving state and in the engaged state, and that the clutch 35 on the other hand in the engaged state , with the longer spring end 58 released by the locking hook 72 , with which the minute drive tube-forming drive shaft 34 is connected via the torque-proof drum 53 via the torque-proof connection. Disengaged, not by driving condition, Figs. 7-10 show other hand, is the coupling 35, the drive shaft 34 for unrestrained, non-driving circulating freely.

Special details of the program wheel 38 are explained below. As program cam 37, this has pins 76 with head 77 which can be inserted radially from the outside inwards. Several such pins 76 are stored as replacement pins in associated bores on the right end face of the hood 12 , so that there are always sufficient pins 76 . The program wheel 38 has an axially projecting collar 78 on the outer circumference with insertion openings 79 for the individual pins 76 that follow one another at equal angular intervals and are shaped in a manner favorable to manufacture. The cam 71 of the spring lever 61 has a smaller radial distance from the axis 28 than the collar 78 , so that the cam 71 thus projects to the right under the collar 78 in FIG. 8. The pins 76 are held with their radially inner end resiliently in the axial direction and secured in the radial direction so that they cannot fall out. At this fuse, a spring washer 80 is attached to the program wheel 38 which is connected to the program wheel 38 to a fixed unit. The spring washer 80 is, for. B. by means of two pins 81, 82 , with end-side snap heads inserted into associated bores of the program wheel 38 . This achieves axial locking and at the same time provides a firm connection in the radial direction and also in the circumferential direction. In addition, the spring washer 80 is centered in the circumferential direction relative to the program wheel 38 . The spring washer 80 has successive spring tongues 83 with somewhat thickened shape ends 84 at the same circumferential angular spacing, which, when the pins 76 are inserted, can positively engage in the associated annular grooves 85 on the pin shaft. When viewed in the circumferential direction, each spring tongue 83 of the spring washer 80 is arranged on the radial region where an insertion opening 79 is located.

The program wheel 38 thus forms a unit with the spring washer 80 . Both parts are made of plastic. In the center, the program wheel 38 carries a sleeve 86 which has a plurality of slots which follow one another in the circumferential direction and which give rise to individual resilient tongues. The slotted sleeve 86 is enclosed by a spring ring 87 and is thus held in a rotationally fixed manner on the hollow shaft 40 , that is to say the 24-hour drive tube, with a predetermined, transmissible torque, the unit comprising the program wheel 38 and the spring washer 80, however, being rotatable for programming purposes while eliminating the frictional engagement . In order to reliably prevent axial misalignment when rotating, the unit consisting of program wheel 38 and spring washer 80 is fixed axially immovably on the hollow shaft 40 . The program wheel 38 is on the back of a part, for. B. a gear 88 , the clockwork drive 39 . On the other axial side there is a slotted spring washer 89 made of metal which presses against the spring washer 80 .

If the user wants z. B. within the 24-hour cycle, that is, one revolution of the hollow shaft 40 and the program wheel 38 , make three feedings, each in the time range of one hour, then three pins 76 at the respective time-bearing point of the program wheel 38 in the insertion openings there 79 inserted from the outside inwards until the spring tongues 83 spring away and the shape end 84 engages securely in the annular groove 85 . The program wheel 38 is then rotated, overcoming the clamping on the hollow shaft 40, relative to the latter in the same rotational position, which is facilitated by the arrow within the housing opening 70 . Then the described process of feeding takes place three times during one revolution of the program wheel 38 in 24 hours.

Through the front cover of the hood 12 , an adjusting button 90 protrudes through an opening, on which the clockwork drive 39 can be adjusted by hand.

The automatic feeding process described has the advantage that the here not abruptly at feeding time Feed is delivered, but the feed delivery via a certain period of about 20 minutes. this has result in a much better utilization of the feed and also takes into account the natural behavior of the fish. It is also advantageous that the feeding device is small, is light, compact and cheap. It enables cheap Handling. Among other things because of the network-independent Drive can be handled easily and the device place in the most favorable place in the aquarium and also trouble-free at any time as desired offset. The implied electrical is also advantageous Safety. Even if the device accidentally should fall into the aquarium tank no danger for the user or the fish in the pool given.

The removable closure cover 29 of the storage drum 27 contains a fixed wing 91 on the inside and also a wing 94 which can be pivoted on a central axis 93 by means of a sleeve 92 . On the latter there is a wall 95 which is approximately perpendicular thereto and a wedge-shaped wall 96 . The pivotable wing 94 can e.g. B. can be pivoted up to a molded stop 97 . In this position the smallest delivery quantity is set. If the pivotable wing 94 is adjusted in the direction of the arrow 98 , the chamber formed in the area of the feed discharge opening and fed from the inside of the drum is enlarged and thus a larger quantity of feed is dispensed over the cycle at 1 revolution per hour.

Claims (35)

1. Automatic feeding device, in particular for aquariums, in a housing ( 10 ) a rotatable storage drum ( 27 ) with a feed discharge opening ( 30 ), a drive device ( 33 ) for the storage drum ( 27 ) and one between the drive shaft ( 34 ) and the storage drum ( 27 ) seated clutch ( 35 ) which can be engaged by means of a set program cam ( 37 ) of a program wheel ( 38 ) which is driven in a time-keeping manner, characterized in that the drive device ( 33 ) consists of a clockwork drive ( 39 ), the minute drive tube rotating at one revolution per hour forms the drive shaft ( 34 ) for the storage drum ( 27 ), and that the program wheel ( 38 ) can also be driven by means of the clockwork drive ( 39 ). 2. Feeding device according to claim 1, characterized in that the program wheel ( 38 ) is driven by the 24-hour drive tube of the clockwork drive ( 39 ) which rotates with one revolution in 24 hours and is designed as a hollow shaft ( 40 ). 3. Feeding device according to claim 2, characterized in that the program wheel ( 38 ) sits directly on the hollow shaft ( 40 ). 4. Feeding device according to one of claims 1-3, characterized in that the clockwork drive ( 39 ) is network-independent. 5. Feeding device according to one of claims 1-4, characterized in that the clockwork drive ( 39 ) is designed as an electrical, in particular quartz-controlled clockwork drive, which is fed by at least one battery ( 18 ) or a rechargeable battery. 6. Feeding device according to one of claims 1-5, characterized in that the storage drum ( 27 ) about a lying axis ( 28 ) is rotatably mounted in the housing ( 10 ) and that the clockwork drive ( 39 ) in the program wheel ( 38 ) and clutch ( 35 ) adjoins an end face of the storage drum ( 27 ) and is arranged coaxially with it. 7. Feeding device according to one of claims 1-6, characterized in that the supply drum ( 27 ) at the driven end has an axle journal ( 43 ) which is received in a coaxial intermediate sleeve ( 45 ) and is coupled to it in the circumferential direction, for. B. by means of a radial web ( 44 ) which engages in an axial recess ( 46 ) of the intermediate sleeve ( 45 ). 8. Feeding device according to claim 7, characterized in that the intermediate sleeve ( 45 ) in a transverse to the axis ( 28 ) of the storage drum ( 27 ) extending, pull-out housing wall ( 14 ) is rotatably mounted and axially displaceably held, in particular by means of both sides of the housing wall ( 14 ) axially abutting rings ( 47, 48 ), and with a sleeve section ( 50 ) passing through the housing wall ( 14 ) protrudes toward the clockwork drive ( 39 ). 9. Feeding device according to one of claims 1-8, characterized in that the coupling ( 35 ) on the one hand on the storage drum ( 27 ), preferably on the projecting sleeve section ( 50 ) of the intermediate sleeve ( 45 ), engages both in the disengaged, non-driving State as well as in the engaged state and on the other hand in the engaged state with the minute drive tube ( 34 ) of the clockwork drive ( 39 ) in a torque-transmitting connection, in the disengaged state, however, the minute drive tube ( 34 ) releases for undamped, drive-free idling. 10. Feeding device according to one of claims 1-9, characterized in that the clutch ( 35 ) is designed as a loop spring clutch. 11. Feeding device according to claim 10, characterized in that the loop spring coupling has a to the axis ( 28 ) of the storage drum ( 27 ) coaxial cylindrical coil spring ( 56 ) which loosely engages with the minute drive tube ( 34 ) detachably and non-rotatably connected drum ( 53 ). 12. Feeding device according to one of claims 7-11, characterized in that the helical spring ( 56 ) with an approximately tangentially or radially bent spring end ( 57 ) in an axial slot ( 59 ) of the intermediate sleeve ( 45 ), in particular the projecting sleeve section ( 50 ) , engages and the other, preferably longer spring end ( 58 ) also projects approximately tangentially or radially and interacts with a locking device ( 60 ) which can be controlled by the program wheel ( 38 ). 13. Feeding device according to claim 12, characterized in that the locking device ( 60 ) has a spring lever ( 61 ) which projects transversely into the orbit of the preferably longer spring end ( 58 ) of the loop spring coupling, the spring end ( 58 ) with the coil spring () 56 ) carries the stopping pawl ( 72 ). 14. Feeding device according to claim 13, characterized in that the spring lever ( 61 ) one in the direction of the program cam ( 37 ) of the program wheel ( 38 ) projecting from this with displacement of the spring lever ( 61 ) (arrow 66 , Fig. 8) and with release of the spring end ( 58 ) of the loop spring clutch ( 35 ) actuatable cams ( 71 ). 15. Feeding device according to claim 14, characterized in that the locking hook ( 72 ) and the cam ( 71 ) project in the same direction and are arranged on the spring lever ( 61 ) at a distance from one another. 16. Feeding device according to claim 14 or 15, characterized in that the spring lever ( 61 ) a from the housing ( 10 ) led out, manually operable handle, for. B. has a lever extension ( 64 ). 17. Feeding device according to one of claims 13-16, characterized in that the locking hook ( 72 ) has an inclined surface ( 73 ) on the back. 18. Feeding device according to one of claims 13-17, characterized in that the spring lever ( 61 ) is held on the side of the housing wall ( 14 ) which faces away from the storage drum ( 27 ), the spring lever ( 61 ) having an approximately circular central part ( 62 ), a lower, on the housing wall ( 14 ) fixed tab ( 63 ) and an upper tab ( 64 ), the lower tab ( 63 ) with the central part ( 62 ) and upper tab ( 64 ) at a free axial distance from the Housing wall ( 14 ) runs and can be rebounded towards it (arrow 66 , Fig. 8). 19. Feeding device according to claim 18, characterized in that the housing wall ( 14 ) at the height of the upper tab ( 64 ) has a guide web ( 67 ) with an opening ( 68 ) therein, through which the upper tab ( 64 ) upwards protrudes. 20. Feeding device according to claim 19, characterized in that the guide web ( 67 ) carries on its axially projecting edge a leading to the locking hook ( 72 ), approximately arcuate control surface ( 69 ). 21. Feeding device according to one of claims 7-20, characterized in that the intermediate sleeve ( 45 ) at a greater radial distance than the sleeve section ( 50 ) one to the longer spring end ( 58 ) of the loop spring clutch ( 35 ) projecting auxiliary cams ( 74 ) with an inclined surface ( 75 ) which, when the supply drum ( 27 ) is rotated in the drive direction (arrow 36 ), axially presses the spring end ( 58 ) struck on the locking hook ( 72 ) while unlocking it from the locking hook ( 72 ). 22. Feeding device, in particular according to one of claims 1-21, characterized in that the program wheel ( 38 ) by means of a slotted sleeve ( 86 ) which is enclosed by a spring ring ( 87 ), non-rotatably with a predetermined torque, but rotatable for programming purposes and by means of a spring washer ( 89 ) is held axially immovably on the hollow shaft ( 40 ) and with the rear side facing away from the spring washer ( 89 ) axially on a part, for. B. a gear ( 88 ) of the clockwork drive ( 39 ). 23. Feeding device according to one of claims 1-22, characterized in that the program wheel ( 38 ) projects with a peripheral portion through a slot-shaped housing opening ( 70 ) through to the outside and is programmable by access from the outside. 24. Feeding device according to one of claims 16-23, characterized in that the handle ( 64 ) of the spring lever ( 61 ) is also brought out through the slot-shaped housing opening ( 70 ). 25. Feeding device according to one of claims 22-24, characterized in that the program wheel ( 38 ) as program cam ( 37 ) radially from the outside inwards insertable pins ( 76 ). 26. Feeding device according to one of claims 14-25, characterized in that the program wheel ( 38 ) on the outer circumference has an axially projecting collar ( 78 ) with successive insertion openings ( 79 ) for the pins ( 76 ) in the circumferential direction at equal angular intervals, and in that the cam ( 71 ) on the spring lever ( 61 ) is arranged at a smaller radial distance than that. 27. Feeding device according to one of claims 22-26, characterized in that the pins ( 76 ) are held with their radially inner end resiliently in the axial direction and secured in the radial direction. 28. Feeding device according to claim 27, characterized by a spring washer ( 80 ) secured to the program wheel ( 38 ) and thus connected to form a fixed unit, which has circumferential spring tongues ( 83 ) with shaping ends ( 84 ) at equal angular intervals, which are in associated annular grooves ( 85 ) engage on the shaft of the inserted pins ( 76 ). 29. Feeding device according to one of claims 26-28, characterized in that each spring tongue ( 83 ) is arranged in the circumferential direction at the level of an insertion opening ( 79 ). 30. Feeding device according to one of claims 1-29, characterized in that the housing ( 10 ) has an approximately trough-shaped base part ( 11 ) in which the storage drum ( 27 ) is rotatably received and that the feed discharge opening ( 30 ) at the end of the Storage drum ( 27 ), which is located opposite the clockwork drive ( 39 ) with program wheel ( 38 ) and clutch ( 35 ), is preferably contained in the wall area of an axially attached sealing cover ( 29 ), with a location in the bottom part assigned to the feed discharge opening ( 30 ) ( 11 ) an opening ( 26 ) is included. 31. Feeding device according to claim 30, characterized in that the side walls ( 20, 21 ) of the bottom part ( 11 ) have ventilation openings ( 24, 25 ) through which air circulates through the opening ( 26 ) and the bottom part ( 11 ) to the outside can. 32. Feeding device according to one of claims 1-31, characterized in that the clockwork drive ( 39 ) together with the program wheel ( 38 ), the coupling ( 35 ) and the housing ( 14 ) carrying the intermediate sleeve ( 45 ) and the spring lever ( 61 ) ) is combined into an overall block which is axially assembled and held together, the entire block as a unit being insertable into and withdrawable from the bottom part ( 11 ) of the housing ( 10 ). 33. Feeding device according to one of claims 1-32, characterized in that the housing ( 10 ), in particular the bottom part ( 11 ), has a battery compartment ( 17 ) at one end, which can be closed by means of a removable cover ( 19 ) and by is accessible from the outside. 34. Feeding device according to claim 32 or 33, characterized in that the entire block is covered by a hood ( 12 ) which is releasably attached to the bottom part ( 11 ), in particular plugged on and / or clipped on. 35. Feeding device according to one of claims 1-34, characterized by a removable, on the bottom part ( 11 ) with outer closure attachable cover element ( 13 ), which connects to the hood ( 12 ) and the bottom part ( 11 ) in the region of the storage drum ( 27 ) covers.