DE1239535B - Device for actuating a valve - Google Patents

Description

Device for actuating a valve The invention relates to a Device for operating the valve of a pressurized container in predetermined Time intervals with a drive pinion, a drive for this pinion and a Pair of gears.

It is known to use various products, e.g. B. insecticides, deodorants, Decongestants, fragrances, lubricating oils and atomized solids in containers to be packaged under pressure of an inert gas. For use they come in the form of a fine sprays, a cloud or an aerosol delivered by a pressure sensitive Valve is operated by hand. In many cases it is desirable to use these substances to be given at periodic intervals. In such cases an automatically operated Valve required.

An automatic device for distributing a fragrance is known. In this device, a lid is placed over a fragrance container periodically raised, including a cam disc and a multi-stage gear, about that the cam is operated can be used. As a result of this multilevel Transmission and its numerous gears, axles and bearings, this is well known Device unwieldy and expensive.

The object of the invention is therefore to provide a device for actuating the Valve of a pressurized container closed at predetermined time intervals create that on the one hand takes up little space and on the other hand consists of a few, There are parts that are economical to manufacture and easy to assemble.

The means by which this problem is solved is in the main claim specified.

An example embodiment of the invention and its mode of operation is described below with reference to the drawing in which FIG. 1 a partial sectional view of the device according to the invention together with a bottom Shows pressure dispensing container; F i g. Figure 2 is a section along line 2-2 from Fig.l; F i g. 3 is a partially sectioned front view of the invention Apparatus showing actuation of the valve of the dispensing container; F. i g. Figure 4 is a partial cross-section showing part of the gear pair with a cam, a cam follower and valve actuators in their relationship shortly before actuating the valve of a container; F i g. 5 shows in the same View as in FIG. 4 the cam, the cam follower and the valve actuation device, namely how they touch and operate each other.

In the drawings, a preferred embodiment of a dispensing device according to the invention is shown and generally designated 10. As shown in FIG. 1, the dispensing device 10 consists of a frame or base element 11 which can be attached to the top of a pressurized dispensing container C in a suitable manner. The frame or base 11 is substantially tubular in construction. The base element 11 in the embodiment shown is provided at the lower end with a groove 12 which corresponds essentially to the rolled edge 13 of the pressurized media container C in terms of shape and dimensions. The base element 11 is preferably made of resilient plastic material, which makes it possible to snap the base element onto the pressurized container, which leads to a firm hold of the base element on the head of the container C.

The walls 14 of the tubular base serve as supports for the operating parts of the device. An inwardly projecting edge 15, the is formed on the uppermost inner wall of the base part, can be shaped so that it forms the support for a circular plate 16 which carries the mechanism. This supporting plate can on their location through additional facilities be held, e.g. B. by bolts 17, which extend through eyes 18 in the inner section of the basic element can be formed, which provides additional strength and rigidity results. A cover 19 can, as shown, protect the mechanism be provided.

An electric or clock spring motor 20 is used to drive this mechanism. Another drive that is used in usefully gives a steady speed, can be used when a precise time interval between valve actuations is not particularly important is.

The motor 20 drives a pinion 21, which is better shown in FIG. 2 to see is on. The pinion, in turn, drives a pair of gears 22 and 23 which rotate characterized by their different number of teeth, z. B. 60 and 64, and where that Gear 23 has a journal bearing 24 which is placed on a journal 25 and so is designed that it can slide on the pin in the longitudinal direction, so that the distance between the parallel gears 22 and 23 can be enlarged or reduced can while the gears are rotating. The gear 22 is also designed so that it rotates on the pin 25, but is held in a fixed horizontal position.

In the non-work position, as shown in FIG. 1 shown is the gear 23 upwards by resilient devices, for. B. a spring 26 held. An essential one Part of the invention is that the two parallel gears 22 and 23 have a different number of teeth and rotate around a common axis and that one gear can move from the other on the common shaft, while the engagement with the drive pinion is maintained.

The gear 22 has a downward sloping cam 28, and the lower gear 23 has a cam follower 29 which is upward, like shown in the drawings protrudes. Both have the same radial distance from the center of rotation. These cams can protrude from the gear body or in other ways be suitably formed thereon. The cam on the gear with the largest The number of teeth should taper upwards in the direction of rotation of the gear, whereas the cams with the lower number of teeth down against the direction of rotation, like in Fig. 4, run obliquely so that the two cams ride on each other can if the faster moving gear the slower with the bigger one Number of teeth outdated. In order for the valve to close quickly, the cam must end suddenly. As can be seen from a comparison of FIGS. 4 and 5 can be seen, the effect of the Cams in it to bring the two gears apart when the cams are against each other be led by. This effect can also be seen by comparing FIG. 1 with F i g. 3 shown.

It is true that only one set of cams could be used to drive the device however, it is evident that when a downward If pressure were applied to the gear at only one point, then it would hang on the peg. It is therefore preferred for the gears 22 and 23 to have three pairs of cams 28, 29; 30, 31 and 32, 33. These are at the same angles, but with different angles radial distance from the axis of rotation, so that several pairs of cams without interfering with each other touch, can be led past each other.

When the cam 28 overtakes the cam 29 while the drive pinion drives the pair of gears, the lower gear 23 is down from the upper gear pushed away. This downward shift can be used to actuate the container valve 40 can be exploited. In a preferred embodiment, there is a protrusion 34 provided on the lower gear. This projection is designed so that it is in Comes into contact with another projection 36 on a hinged clevis 35, who actuates the valve button 40. The clevis can be attached to a suitable part of the Valve actuating mechanism as shown, be hinged. To minor irregularities to compensate for valve button construction and height, and to avoid overshooting To prevent the engine from running when the valve button 40 is too high, the cam should 36 have a spring-like character, so that it yields when a pressure is greater than that required to operate the valve.

To operate the automatic valve operating mechanism According to the invention, the actuator is fixed to the container from which the material is dispensed should be attached. Any suitable method of securing the mechanism can be used as long as the valve pusher is not disengaging from the valve button moved when pressure is applied. Care must be taken that the Cams or protrusions 34 on lower gear 23 and 36 of clevis 35 in Operating position are aligned with one another, as shown in FIG. 5 shown when that Pair of cams 28 and 29 is also aligned with one another in operation. The cams 34 and 36 should be at a point above the valve button for operation are effectively related to each other, perpendicular to the axis of the joint, to which the fork head 35 is attached. If you use two or more pairs of cams between the gears 22 and 23, their relative positions do not matter, rather, one prefers that a sentence in an operational relation to one Point above valve head 40 is when the valve is actuated, as in FIG. 5 shown.

When the gears and cams are brought into operative position what usually happens when the device is assembled, and it does not need to be changed afterwards, then it is the one that actuates the valve Mechanism ready to go into action. When driven by an electric motor this can be started by inserting a plug on line 42 into an electrical Voltage source is plugged.

Is it a mechanism with a drive pinion eight teeth and the gear 22 has 60 teeth and the gear 23 64 teeth, so is eight full revolutions of the pinion to one full revolution of the gear 23 necessary. During the same time, gear 22 moves 64 teeth or one Rotation plus the distance resulting from four gear teeth. This means, the gear 22 runs four teeth faster with each revolution of the gear 23 than the gear-23. Eventually, as can be seen, that overtakes gear 22 the gear 23, and the cams 28 and 29 come into action and push the Gear 23 down, as in F i g. 5, and in turn the cam engages 34 in the cam 36 and pushes the clevis 35 down, and the valve is actuated.

The valve remains in the depressed state as long as the cams 28, 29 and 34, 36 are engaged. The effective actuation area or the radial one Length of these two cams have when determining the length of time during which the gear 23 is depressed, a share. Since the gears 22 and 23 Rotate in the same direction, but at different speeds, must be the relative Rotation taken into account when calculating the time the valve is depressed will. Similarly, the lengths of cams 34 and 36 are determined by the length of time determined, which is desirable, during which the valve head remains depressed should, of course, the relative speed of rotation of the gears 22 and 23 taken into account must become. Usually, but not necessarily, is the operative actuating surface of the cam 36 longer than the actuating surfaces of the cams 28 and 29, namely in view of the fact that the clevis 35 does not rotate.

In a preferred embodiment of the invention, the lower gear is depressed by the valve actuating cam 34 once every sixteenth revolution of the lower gear, and this depressing occurs while the cam 34 is above the valve 40 of the container. This is quickly achieved by providing the gears 22 and 23 with a suitable number of teeth, e.g. B. 60 and 64, as previously described, can be selected. The number of teeth on these gears should be chosen so that the number of teeth of one gear with the largest number of teeth, multiplied by an integer, is equal to the product of the same integer plus 1 times the number of teeth on the other gear. In the case shown, this is z. B. 64 -15 = 60 - 16. Another suitable gear pair could e.g. B. be one with 52 or 48 teeth (52 - 12 = 48 - 13).

As can be seen from the foregoing, there is an infinite variety of combinations for valve actuation possible. The change in speed of the drive pinion, the number of teeth of the gear pair and the length of the actuating surfaces the cams can be included. Fortunately, these factors can get through relatively simple mathematical calculations can be established.

Of course, the housing 11 must have an opening (not shown), through which the spray mist can pass from the opening 41 of the valve head. Facilities, to bring the device actuating the valve in place, so that the opening is always aimed at the spray, can optionally be provided.

Claims (7)

Claims: 1. Device for operating the valve of a lower Pressure standing container at predetermined time intervals, with a drive pinion, a drive for this pinion and a pair of gears, characterized in, that the gears (22, 23) rotatably mounted on a common pin (25) are, the teeth of which engage the teeth of the drive pinion (21) and where one gear of the gear pair has a larger number of teeth than the other and the lower gear (23) rotate freely and on the pin of the upper gear (22) can slide away when a downward pressure is applied to it, the tooth-in-tooth contact with the pinion gear (21) being maintained; that also the upper gear (22) rotatable, but not sliding on this pin (25) sits and that a spring (26), which normally the lower gear (23) in an upper layer parallel to the rotatable, but axially non-displaceable gear (22) holds, and a downwardly protruding cam (28) on the upper gear (22) and an upwardly projecting cam (29) is provided on the lower gear (23) are and that these cams are the same radial distance from the center of rotation of the gear pair and the cam on the gear with the lower number of teeth on the cam of the gear with the larger number of teeth rides, while the faster moving one Cam overtakes the slower moving one and the lower gear (23) down pushes, thereby actuating a valve head (40) on a pressurized container to which the actuator is attached. 2. Device according to claim 1, characterized in that the drive device is a clock spring motor, the the drive pinion rotates at a constant speed. 3. Device according to Claim 1 or 2, characterized in that the gear pair of gear wheels with such a number of teeth is chosen that the number of teeth of the gear with the The largest number of teeth multiplied by an integer results in a product that is equal to the product of this same whole number increased by 1 with the number of teeth of the other Gear is. 4. Device according to one of the preceding claims, characterized in that that the lower gear has the largest number of teeth. 5. Device after one of the preceding claims, characterized in that the lower gear 64, the top has 60 teeth. 6. Device according to one of the preceding claims, characterized by a downwardly protruding projection (34) on the underside of the lower gear (23) which can actuate the valve head (40) while the cams on the gear pair mesh and the lower gear after is moved down. 7. Device according to one of the preceding claims, characterized by additional, downwardly projecting cams (30, 33) on the upper gear (22), which on additional, upwardly projecting cams (31, 32) on the lower gear (23) are matched, each downwardly protruding cam has a different radial distance from the center of rotation of the gears, and each upwardly protruding cam also has such a different radial distance, further each of the downwardly protruding cams (30, 33) the same radial distance from The center of rotation has, like one of the upwardly projecting cams (31, 32), so that cooperating pairs of cams are formed. B. Device according to one of the preceding claims, characterized by a hinged fork head (35) parallel to the pair of gears (22, 23), the lower surface of which rests on the valve head (40) and which has a resilient projection (36) on the upper side, which with the underside of the gear (23) or the projection (34) cooperates to actuate the valve head (40) when the gear (23) is moved downwards. Documents considered: German Auslegeschrift No. 1125 225; U.S. Patent Nos. 2,613108, 2 971382, 3018056.