RU2229348C2 - Metering device for reservoir, method for making and filling such reservoir with metering and(or) filling adaptor - Google Patents

Abstract

FIELD: processes and equipment for metering fluids. SUBSTANCE: device connected with reservoir for metering fluid has opening and locking member engaged with said opening and made with possibility of motion between position for closing opening and position for keeping it open. Part of metering device is preliminarily made as one piece together with mouth of reservoir; remaining part of device is connected with reservoir. Part of metering device which is preliminarily made in mouth of reservoir includes means for fixed holding of locking member in one of its positions and (or) means for shifting locking member to one of its positions. Metering device also includes pump arranged between reservoir and outlet opening and movable unit connected with pump for functioning it. Metering device also includes system for preliminary compression; several ducts connecting pump with reservoir and (or) with outlet nozzle are made as one piece. Method for making reservoir with metering device and filling it with fluid comprises steps of making reservoir; preliminarily making part of metering device in mouth of reservoir, making remaining part of metering device, filling reservoir with fluid; closing reservoir due to joining remaining part of metering device with said reservoir. Reservoir may be preliminarily made by means of injection molding and pneumatically shaping for imparting final shape to reservoir before filling it. EFFECT: simplified design, lowered cost price, decreased number of operations according to method, enhanced efficiency. 45 cl, 54 dwg

Description

The present invention relates to a metering device connected to a container for dispensing a fluid comprising at least one opening and at least one locking element cooperating with the opening and configured to move between a position locking the opening and a position in which the opening remains open. This metering device is known, for example, as a nozzle for a bottle of water or a bottle for drinking.

The term “fluid” in this context means any non-gaseous fluid, as well as liquids, including finely divided, powdered solid materials.

A known metering device is typically removably connected to the container, for example screwed onto the neck of the container, after filling and filling the container. The dispensing device forming an autonomous unit is usually performed separately or assembled from several elements.

The known metering device therefore has the disadvantage that it has a relatively large number of elements, and also its implementation and assembly with a (filled) container are relatively difficult. Both the manufacture and assembly of the metering device are therefore expensive and time consuming, which is currently a definite disadvantage when a large number of such bottles are used.

Therefore, it is an object of the present invention to provide a metering device for a container of the type described above in which the aforementioned disadvantages are eliminated. According to the invention, this problem is solved due to the fact that at least part of the metering device is preliminarily performed on the neck of the container, and the rest of the metering device is connected to it. This preliminary attachment of a portion of the metering device to the neck of the container provides the advantage that the assembly of the metering device actually coincides with the installation of the metering device on the container, resulting in a reduced number of operations. In addition, the rest of the metering device takes a lighter and simpler form than conventional metering devices, since it will not be used or processed as a separate part, so it can provide strength and rigidity due to capacity.

The portion of the metering device previously made on the neck of the container is preferably performed integrally with this neck. Thus, the number of individual elements is reduced, and therefore assembly is simplified. A subsequent reduction in the number of elements can be ensured when the neck, in turn, is formed at the same time as the container.

A portion of the metering device previously made on the neck may, for example, comprise means for rigidly holding the locking element in at least one of its positions or means for displacing the locking element in one of its positions. This biasing means may preferably comprise at least one spring.

In another embodiment, the dispensing device also comprises at least one pump located between the container and the opening, the pump having a suction side and a discharge side, the dispensing device also comprises a movable means connected to the pump for its operation, means connected to the suction side a pump for supplying fluid from the tank, and at least one outlet nozzle connected to the discharge side of the pump. Thus, the dispensing device ensures the implementation of the spray nozzle, well known in the example of spray guns, for example, for detergents.

The spray nozzle known in the art comprises a housing that can be fixed, usually screwed onto the neck of a container or bottle, in which a manually actuated piston pump is mounted. To actuate the pump, the starting device is pivotally attached to the housing. The suction side of the pump is connected to a tube that extends sufficiently long into the bottle, usually to a position near the bottom, whereby a fluid, which is usually a liquid, can be extracted through the tube. The discharge side of the pump is connected to the outlet nozzle of the spray nozzle via a channel. The return element, which is usually a bias spring, is made in the pump in such a way that it pushes the piston back to its idle position at the end of the pump stroke. The spray nozzle according to the prior art is usually screwed onto the bottle on the filling line, and then the bottle is completely filled.

This spray nozzle in the prior art has the disadvantage that it has a relatively large number of parts, and its assembly is relatively difficult. Therefore, the manufacture and assembly of the spray nozzle is an expensive operation and takes a lot of time, which is especially inconvenient, given the significant increase in the number of bottles used at this time. Moreover, various details of the spray nozzle in the prior art are made of different materials, which is a problem from the point of view of loading and unloading and reuse of the bottle with the spray nozzle after its contents have been used up.

The aforementioned disadvantages are eliminated in the metering device or spray nozzle according to the invention due to the fact that at least part of the spray nozzle is pre-formed together with the container, and the rest of the spray nozzle is attached to it.

The portion of the metering device that is preformed together with the container may preferably comprise at least a portion of the functional means. If, for example, the pump is a piston pump and the piston of the pump is connected to means for biasing it to its original position, then this piston biasing means, which may preferably comprise at least one spring, is attached to the container. Structurally simple implementation is realized when the spring is a bending and / or torsion spring.

To simplify the assembly of the metering device and improve its functioning, the piston displacement means are preferably adapted to interact with the functional means of the pump. This eliminates the need for the piston displacement means to pass into the pump or to be carried out in the pump. As a result, the air-filled space in the pump occupied by the conventional piston bias springs is eliminated, and as a result, the pumping action is improved. Moreover, the choice of materials for the piston displacement means is not of particular importance, since it will not be in contact with the fluid.

It should be noted that in this case, the functional means is preferably connected to the piston so that it is fixed under the influence of tension and compression, for example, latches onto the piston so that it performs all the movements of the functional means.

The pump preferably has a housing to which the functional means is movably attached. When the functional means comprises starting means which pivotally latches onto the pump casing, a metering device convenient from the point of view of assembly is provided.

According to an embodiment of this embodiment, the pump comprises a working cylinder and an exhaust cylinder made next to it, while the functional means is arranged to displace the pistons in these cylinders synchronously. In this case, the functional means preferably comprises a pushing member, and the piston, or each piston, is integral with the pushing member.

In accordance with another embodiment of the present invention, the dispensing device comprises a blocking means cooperating with the functional means, while the blocking means may comprise at least one brittle protrusion in the way of the functional means or in a cap covering the outlet nozzle.

According to another embodiment of the present invention, the metering device is provided with a pre-compression system arranged between the pump and the outlet nozzle, the pump, the pre-compression system and part of the passages connecting the pump to the tank and / or the outlet nozzle, are integral.

A very simple assembly is provided when the rest of the metering device is connected by a snap connection to the neck of the container or to the portion of the metering device pre-formed on it. Therefore, the connection between these parts can be quickly and easily brought in a single movement.

In accordance with yet another embodiment of the present invention, a supply element is provided that is in fluid communication with a container and has at least one outlet, and a metering element is hermetically connected to the supply element and has at least one outlet opening a metering chamber, the feeding element and the metering element being rotatable relative to each other in order to determine different doses.

This embodiment of the invention forms a dispensing cap for a compressible bottle filled with a fluid.

By turning the feed element and the metering element, the outlet of the metering element can be combined with the outlet of the feed element. When the bottle is subsequently compressed, the fluid will be pushed up into the supply element, and then will pass through the outlet openings of the supply element and the metering element into the metering chamber. After relieving pressure on the compressible bottle, the fluid, due to the vacuum inside the bottle, will be drawn back from the metering chamber through the outlet openings of the metering and supply elements. This retraction of the fluid ends when it is drawn into the air. This will happen when the corresponding outlet of the metering element is above the level of the fluid in the metering chamber. The selection of the height of the combined outlet openings determines the level of liquid that will remain in the metering chamber after the bottle has stopped compressing and which can then be poured and used.

This dispensing device, which allows dispensing liquids in a simple manner and with relatively high accuracy, can, for example, be used for dispensing animal feed or medicines and in order to measure the amount of cleaning substances and the like.

In a preferred embodiment of this metering device, the supply element and the metering element comprise a substantially cylindrical wall, the presence of which improves sealing between the elements. Preferably, the axial channel is formed in the feed element in the form of a recess in its cylindrical side wall, and the dispensing element contains a plurality of outlet openings spaced at intervals in the peripheral direction and in the axial direction, as a result of which it will be possible to dispense different doses of the fluid.

Additional, preferred embodiments of the metering device according to this invention are set forth in dependent claims 30-37.

The metering chamber and the container are preferably preformed by injection molding; according to the invention, the container is advantageously carried out by pneumoforming until it is finalized after pre-molding. In this way, a preformed container is obtained with a portion of the metering device already on it, which is easy to store and transport, and also assembled using a small number of operations for the manufacture of a finished final product.

This invention also relates to a unit (neck) of a container and a metering device connected to it according to the foregoing. This assembly is structurally simple and can be manufactured at low cost, has a smaller than usual number of elements and, in addition, can be relatively light.

The present invention also relates to a container for use in the assembly described above. Such a container, on which a part of the metering device is preliminarily made in this way, provides the above advantages with respect to ease of assembly, cost, etc., as compared to conventional containers, which only provide for attaching the metering device, for example, in the form of a screw thread on the neck.

Finally, the present invention relates to a method for manufacturing and filling with liquid a container with a metering device. This method is also known. According to the usual method, the container or bottle is carried out in the first place, usually by means of pneumoforming, and sent to the filling line. Here, the bottle is usually provided with a locking means, such as a screw thread near its filling opening or neck. The metering device, which is made of a relatively large number of different elements, is assembled elsewhere and is also provided with attachment means such as a screw thread. Then this nozzle is sent fully assembled to the bottling line. On the filling line, the bottle is filled, after which the nozzle is attached, for example, to a thread on it.

The disadvantage of this method is that the manufacture and filling of the container and the metering device require a relatively large number of operations that do not fit together and cannot be integrated, and therefore this method requires a lot of time and cost. In this case, the finished nodes are already performed at a relatively early stage in the known method, and they have a relatively high cost compared to the final product, which leads to costs associated with possible rejection at a later stage. Finally, after their manufacture, empty containers occupy a relatively large space during transportation and storage before filling.

Therefore, the objective of this invention is to create a method of the type described above, according to which these disadvantages are eliminated. This objective of the present invention is solved by a method including operations according to which the container is carried out, a portion of the metering device is first performed on its neck, the rest of the metering device is performed, the tank is filled and closed by connecting the rest of the metering device to it. Due to the preliminary execution in this way of the part of the metering device assembly only on the filling line, the total number of operations is reduced, as a result of which productivity is increased and cost is reduced.

The portion of the metering device previously made on the neck is preferably carried out at the same time and simultaneously. In this way, the number of elements is reduced, and the assembly is thus simplified and accelerated. Moreover, the neck is performed at the same time and simultaneously with the capacity.

When the container is preliminarily performed by injection molding and pneumoforming to give it the final shape before filling the container, the space occupied by the container before filling is reduced, which reduces the cost of transportation and storage. In addition, the elements of the metering device, having a relatively complex shape, can be performed simultaneously and at the same time with the tank by a simple method using injection molding. According to this invention, it is advisable to make the container from an elastic deformable thermoplastic plastic, for example, from polyethylene terephthalate, so that the elements made integrally with the metering nozzle have sufficient strength and the container can be conveniently made by pneumoforming.

A quick and convenient method is carried out due to the fact that the rest of the metering device is connected using a snap connection with the neck of the container, and then both parts can be connected to each other in one motion.

The container is preferably filled in suspension. In contrast to the conventional filling method, when the containers are transported and filled in a standing position, the equipment used for filling according to the invention does not need to be adjusted so that it can work with containers of different volumes and correspondingly different heights.

According to another embodiment, the remainder of the metering device comprises a pump with a displaceable element adapted to move between the first and second positions, wherein the displaceable element is moved to its second position before closing the container, and moved to its first position after closing the container, to draw fluid into the pump. After that, the dispenser made of the tank with its dispensing device is ready for use.

The invention is further illustrated by the example of several embodiments, with reference to the accompanying drawings, in which:

Figure 1 is a schematic view in longitudinal section of a container that has not yet undergone pneumoforming and on which part of the metering device is made.

Figure 2 is a more detailed schematic view, in longitudinal section of the container shown in Figure 1, in a pneumoformed state, with the rest of the metering device mounted on it.

Figure 3 is a view corresponding to Figure 2 of the metering device in its closed position.

FIG. 4 is a perspective view of a container according to a second embodiment of the invention, prior to pneumoforming and with a portion of the metering device and handles for carrying it, in addition to the rest of the metering device.

Figure 5 is a perspective view of the container assembly and nozzles after pneumoforming, assembled.

Fig.6 is a horizontal projection of the node shown in Fig.5.

Fig.7 is a longitudinal section with a more detailed image of the container and nozzle shown in Fig.5 before assembly.

Figures 8, 9 and 10 are images corresponding to Figures 4, 5 and 6 of a second embodiment of the present invention.

11 is a partial cross section of a detailed image of the container and nozzle shown in Fig.9, complete.

12 is a schematic view of various operations of a method according to this invention.

Fig is a perspective detailed view of the neck of the tank and means of bias, made integral with him, according to the first embodiment of the present invention.

Fig.14 is a side view of the container shown in Fig.13, and part of the spray nozzle connected to it,

Fig. 15 is a view corresponding to Fig. 14 of the container and spray nozzle assembly.

Fig. 16 is a perspective view of the assembly shown in Fig. 14.

Fig.17 is a view corresponding to the view shown in Fig.14, in partial section.

Fig. 18 is a perspective view of a container assembly and a spray nozzle according to a preferred embodiment of the present invention.

Fig is a perspective view with a spatial exploded view of the elements of the spray nozzle shown in Fig.

FIG. 20 is a partial sectional view of the spray nozzle shown in FIG. 19, assembled, during the stroke of the piston.

Fig. 21 is a view corresponding to Fig. 20 of the spray nozzle during the return stroke.

22 is a perspective view of an alternative embodiment of a spray nozzle biasing means.

23 is a perspective view of an alternative embodiment of an assembly consisting of a spray nozzle and a retaining ring for connection to a container.

Fig. 24 is a perspective view of the spray nozzle and retaining ring shown in Fig. 23 and a container connected thereto.

25 is a schematic view of various operations of a method according to a first embodiment of the present invention.

Fig is a perspective view with a spatial separation of the elements of the tank having a metering device according to the first embodiment of the present invention.

Fig. 27 is a perspective view of the container and metering device shown in Fig. 26, complete.

Fig. 28 is a longitudinal section of a container and a metering device shown in Figs. 26 and 27.

Fig.29 is an enlarged detailed view of the dispensing device shown in Fig.28.

Fig. 30 is a view corresponding to Fig. 29 of an alternative embodiment of a metering device.

Figa and 31B is a vertical projection and a perspective view from below, respectively, of the functional element of the metering device.

Fig.32, 32A and 32B is a perspective view and section along the lines aa and bb, respectively, of a two-cylinder pump of the metering device.

Figa and 33B is a perspective view of a separate exhaust nozzle having a built-in blocking means.

Fig, 34A and 34B is a perspective view and section along the lines aa and bb, respectively, of a prefabricated container having a return means of the metering device.

Fig. 35 is a view corresponding to Fig. 26 of another embodiment of a metering device.

Figa and 36B is a longitudinal section and front view, respectively, of the exhaust nozzle used in this metering device, and

Fig. 37 is a perspective view from below of a functional means comprising a blocking means of this dispensing device.

Fig is a perspective view of a horizontal projection with a spatial separation of the parts of the container with a metering device according to this invention.

Fig. 39 is a longitudinal section of a container with the complete dispensing device shown in Fig. 38.

Fig. 40 is a detailed, on an enlarged scale, view of the dispensing device shown in Fig. 39.

Fig - perspective view from below of the dispensing element of the device shown in Fig.

Fig. 42 is a perspective view from below of the lid and the feeding element of the metering device.

Fig. 43 is a perspective view of a horizontal projection of a container and a metering chamber in a preformed condition.

Fig. 44 is a perspective view of a preformed container of another embodiment of the present invention.

Fig. 45 is a perspective cross-sectional view of the container blank and the functional element or cap shown in Fig. 44 that is part of the metering device.

Fig. 46 is a partial sectional view of the metering device and the neck of the container assembly, at the beginning of the inner stroke, and

Fig. 47 is a view corresponding to Fig. 46 at the end of the inner stroke.

The container 1 with the portion 2 of the metering device 3 preliminarily made on it is carried out according to the invention as follows: first, it is molded in the form of a “test tube” and a so-called “blank” 4 is obtained (FIG. 1), and then this blank 4 is subjected to pneumoforming to obtain capacities. As mentioned above, the workpiece 4 already contains a portion of the metering device 3, in this embodiment, a cup-shaped accommodating part 2 is shown, into which the remaining part 5 of the metering device 3 is slidably inserted. This cup-shaped part 2 also has a means for fixedly holding the sliding device part 5 in two end positions, in the form of two grooves 6, 7, which interact with the rib 8, available on made with the possibility of sliding part 5.

In the shown embodiment, the rest of the 5 metering device 3 forms a locking means for the outlet 9 of the container 1. It contains a cylindrical body with a continuous outlet 10, a thickened edge 11, a locking element 12, which is suspended by the ribs 13 in the middle of the outlet channel 10, while leaving open passage openings on all sides, and which has a rounded end edge 14 corresponding to the neck 15 of the container 1.

When filling the container 1 with the contents, part 5 moves outward from the position shown in FIG. 3, in which the outlet 9 is closed by a locking element 12 and in which part 5 is fixedly held by the interaction of the rib 8 with one groove 7 by pushing the portable edge 11, while rib 8 does not fall into another groove 6 (Figure 2). In this position, the locking element 12 is located at some distance from the edge 15 of the neck, so the outlet 9 remains open. The contents of the container 1 can then bypass the locking element 12 through the outlet channel 10.

In another embodiment, the assembly 17 of the container 1 of the metering device 3 according to the invention, two grip parts or handles 16 are also made on the (workpiece) of the container at the same time as the workpiece 4 and part 2 of the nozzle 3 are made integral with it (Figs. 4, 5). This is especially important for relatively large containers with a capacity of several liters, such as packaging for soft drinks, beer or wine. Handles 16 can have different shapes, for example, such as in Figs. 8 and 9. Together with a container, it is possible to make more or less than two handles 16.

As indicated above, the container 1 with the nozzle 3 part 2 made on it is made according to the invention in such a way that the relatively thick-walled container blank 4 and the part of the metering device 3 made at the same time are first performed in the first place 18 according to the corresponding production technology, for example, injection molding, in combination , as an option, with other jointly made elements, such as handles (Fig, block 19). Since this preform 4 has a much smaller volume than the finished tank 1, the cost of transportation and / or storage is relatively low. This method of performing the container has the additional advantage that the parts can be connected to the container by sliding them on the workpiece 4, as a result of which they will be fixedly clamped between the metering device 3 and the container 1 after it takes its final shape due to pneumoforming.

The remaining part 5 of the metering device 3 is then performed in the same or another place 20 using the appropriate technology, for example using injection molding (block 21). After cooling and removal from the injection mold, the various parts are then transported (block 22) to another place 23, where filling and final assembly are carried out.

Part 5 of the nozzle 3 is fed through a buffer 24 to the positioning station 25. The workpiece 4, made at the same time with the part 2 of the nozzle 3 and with other possible elements, is fed from the block 26 to the filling line, where at the first station 27 the workpiece 4 is heated and then compressed into a container 1 with the desired final shape. For this, the workpiece 4 has an edge for manipulating it, in the shown embodiment, the protruding lower side 37 of the cup-shaped part 2, for which it can be taken and clamped. Therefore, this is a two-stage process for pneumatically forming a container 1. It is also possible to form a container by means of a one-stage process, according to which, in the same equipment, the workpiece 4 is injection molded and, when it has not yet cooled, it is finalized by blow molding.

After passing through the buffer 28, the thus formed container 1 is then filled in the next station 29 with a fluid, usually a liquid, for example a soft drink, liquid detergent or the like. In this technical solution, the presence of the edge 37 is advisable in that the container 1 can be suspended on it in a filling machine. Unlike conventional filling stations where the container 1 is transported in a standing position, this filling station 29 does not therefore need to be adapted for containers of different volumes and different heights.

Finally, at the next station 30, the filled container is closed by setting the rest of the 5 metering device 3 on it. The assembly 17 made in this way then goes through the usual steps of labeling (block 31), packing in boxes (block 32), installing on pallets and packing with using a tightening film (block 33), where between these steps are the usual buffers 34, 35 and 36.

According to another embodiment, the dispensing device is a spray nozzle 101 for a container 102 (FIG. 14) comprising a pump 103 having a suction side 105 and a discharge side 106. The movable functional means 104 is connected to a pump 103, and in the embodiment shown, it consists from a trigger 113 having a trigger 115 placed around the rotary shaft 114. The tool 107 is connected to the suction side 105 of the pump 103 for supplying fluid from a container containing a channel, the free end of which is connected to the pipe Coy 123 extending into the container. The discharge side 106 of the pump 103 is connected to the exhaust nozzle 108 through the channel 109. In the shown embodiment, the pump 103, the functional means 104 and the exhaust nozzle 108 are made in the frame 122, which can be attached to the tank 102 as described below.

The pump 103 is a piston pump, consisting of a pump housing or cylinder 110 and a piston 111, reciprocating within it. The piston 111 is connected to the piston rod 112, which in turn is connected to the trigger 113. To return the piston 111 and the trigger 113 to their idle position at the end of the pump stroke, the spray nozzle 101 comprises biasing means 116. In the embodiment shown, the biasing means performs a plurality of parallel bending springs 117 that engage the trigger 113. When the trigger 113 is rotated around the rotary shaft 114 toward the pump 113 and the piston 111 passes into the cylinder 110, the spring 117 bends. When the pressure on the starting device 113 ceases to act, it is pressed into its inoperative position by the springs 117, bending backward. Since the starter is connected to the piston 111 in such a way that it remains fixed during both tension and compression, the piston 111 is then pushed back to its idle position. The connection between the starter 113 and the piston 111 is created by the piston rod 112, which is snapped onto the piston 111 and connected to the starter 113 by means of a hinge made of a film. The snap connection between the piston rod 112 and the piston 111 is made by the head 127 of the piston rod 112, which latches into the corresponding hole 128 in the piston 111.

Each of the springs 117 has a closed loop and is attached at one end 118 to a column or “spine” 119, and the opposite side of each spring 117 has a protrusion 124 that enters the cavity 125 in the trigger 113. Column 119, which consists of a curved tape 120 and made reinforcing ribs, has a partially cylindrical base 129, which is attached to the neck 130 of the tank 102. The base 129, the column 119 and the springs 117 are made integral with the capacity 102. At the base 129, two opposite holes 131 are made with the possibility of interaction with two protruding snap-fit elements 32 on the frame 122, on which the pump 103 is mounted, the functional means 104 and the exhaust nozzle 108. This frame 122 also contains a cylindrical lower part or skirt 133, which can be inserted into the neck 130 of the tank 102 due to a snug fit. and at the same time constitutes a gas and liquid tight seal with an inner edge 134 of this neck. The frame 122 also includes an edge 135 and a shoulder 143, which in the assembled state of the spray nozzle 101 abuts against the upper edge 136 of the neck 130.

Since part of the spray nozzle 101 in the illustrated embodiment of the biasing means 116 forms a part of the container 102, therefore, the assembly of the spray nozzle 102 finally occurs when the container 102 is filled and then closed by a frame 122 on which various elements of the spray nozzle 101 are placed. As part of the operations related to the assembly of the spray nozzle 101 is essentially an integral part of the final assembly and is also necessary, the total number of operations performed to perform the spray bottle Flax nozzle, substantially below normal in the number of conventional fully pre-assembled spray nozzles. Moreover, the number of individual elements is significantly reduced in comparison with a conventional spray nozzle, since some elements are made integral with the tank.

To assemble the remaining parts of the spray nozzle, bending springs 117 must be introduced into the cavity 125 of the trigger 113. To do this, the piston 111 must be moved to its outer position. Then, the rest of the spray nozzle 101 must be pressed into the neck of the container 102 and locked there by means of snap elements 132 engaged with the holes 131.

According to another embodiment of the spray nozzle assembly 101 and the container 102, which is the preferred embodiment (FIG. 18), the biasing means 116 takes the form of individual bending springs 117 extending substantially parallel to the longitudinal axis of the container 102 and not perpendicular to it, as in the first embodiment. These bend springs 117 cooperate with ribs 152 formed in the cavity 125 of the trigger 113. In this embodiment, the trigger 113 has a continuous rotary shaft 153 that enters the free space 154 in the frame 122 and is locked in it by means of a flexible latching lever 155. The shaft 153 of the trigger device 113 and the free space 154 are located above the spray channel 109, the hole 156 is made in the trigger device 113, through which the end of this channel 109 passes, on which the spray nozzle 108 is made. e apparatus further comprises protruding cams 157, which are directly included in the piston 111. The port 68 therefore this embodiment has no separate piston rod.

On the other hand, it is also possible, for example, to make the container 102 and the springs 117 of less flexible material in order to use combined bending and torsion springs deformable in different directions instead of the bending springs 117 shown (FIG. 22). These combined bending and torsion springs 117 comprise, in the shown embodiment, a fastener 169 connected to the reservoir 102 and a torsion spring 170 located perpendicular to it and extending in two directions. The bend springs 117 are attached to the free ends 171 of the torsion spring 170 and themselves have a curved shape, for example in the form of an inverted letter U. Therefore, the springs 117 can also be integral with the container 102 if it is made of less flexible material.

In this embodiment, a pre-compression system is shown made between the cylinder 110 and the spray passage 109 comprising an annular space 158 connected to the cylinder 110 and closed by an elastic flexible diaphragm 159, creating a gas and liquid tight seal.

The space 158 is limited by a cylindrical sleeve 160, which enters the cavity 161 in the frame 122 and is made integral with the diaphragm 159 in the shown embodiment. An opening 162 is made in this cylindrical sleeve 160, in which the movable valve 163 is located and which is connected to the fluid suction passage 107 through the opening 167 in the frame 122. In the shown embodiment, this valve 163, which can hermetically seal the opening 167, is also integral with the sleeve 160. In this case, the locking element 164 is connected to the diaphragm 159, which serves as a limiter for the bending of the diaphragm 159. The cylindrical sleeve 160 is locked in the cavity 161 by the frame 122 using the end wall, which is integral with the capacity 102 .

The pre-compression system 140 operates in a known manner to prevent fluid from moving from the reservoir 102 into the spray nozzle until a predetermined pump pressure is reached. If the fluid is sprayed through the nozzle 108 at too low a pressure, then this fluid is not sufficiently sprayed and the droplets generated in the spray cone are too large. To avoid this, the connection between the container 102 and the spray nozzle 108 is closed by a diaphragm 159, which is pressed against the rim 166 of the spray channel 109, acting as a supporting surface under the influence of the internal voltage, determined by the dome configuration and amplified by the available pressure behind the diaphragm 159. The diaphragm 159 will raised from the supporting surface 166 only when sufficient pressure is created in the cylinder 110 when the piston 111 is moved to its final position, for example, a pressure of the order of 0.3 MPa.

The spray nozzle 101 operates as follows.

If the user needs to spray the fluid from the reservoir 102, then he first pulls the handle 113. In this case, the air present in the cylinder 110 and which cannot get back into the reservoir 102 due to the opening 167 closed by the valve 163, is compressed by the piston 111. When the air pressure is high enough at the end of the pump stroke, then the diaphragm 159 rises from the supporting surface 166 and provides an outlet for air.

During the subsequent return stroke provided by the biasing means 116, the fluid is drawn from the reservoir 102 through the tube 123, the passage 107 and the openings 162, 167 into the cylinder 110 until it is completely filled at the end of the return stroke or the suction stroke (Fig. 18A). In order to prevent the occurrence of a partial vacuum in the container 102 during this stroke, an aeration hole 151 is made in the wall of the cylinder 110, which opens when the outer peripheral sealing lip 139B passes the hole 151 while moving inside the piston 111, and which again connects to the closed space limited between the outer and inner peripheral sealing edges 139B and 139A of the piston 111 during the outer stroke of the piston 111.

The spray nozzle 101 according to this embodiment of the invention is assembled by inserting an annular sleeve 160 and a suction tube 123 into a cast frame 122. Then, the piston 111 is inserted into the cylinder 110, and the trigger 113 is latched by the rotary shaft 153 into the hole 154 of the frame 122. Thereafter, the trigger 113 and the piston 111 are latched together, after which the spray nozzle 108 can be attached to the end of the spray channel 109. In this way the assembly is then inserted into the neck of the container 102 so that the latching element 132 of the frame 122 snaps into the holes 131 in the sides 129 above the neck 130 of the container 102. This embodiment is therefore easier to implement than the first embodiment.

The full path to forming, assembling and filling the container 102 and the spray nozzle 101 is as follows.

In the first place 144, injection molding (FIG. 25, block 174) of the frame 122, on which the cylinder 110 of the pump 103, the suction passage 107 and the spray channel 109 are located, is also carried out. The trigger device 113 is also performed by injection molding (block 175) , a piston 111 (block 176), a sleeve 160 (block 177) and a spray nozzle 108 (block 178). All these elements are collected in block 179. If necessary, the suction tube 123 can be pre-installed (block 180).

In the same place or in another place, a container 102 (block 181) is preliminarily executed, and also a part of the spray nozzle formed in one with it in the embodiment shown above on the displacement means 116. The various elements are then moved (block 182) to another place where operations are performed filling and final assembly.

The already assembled (block 183) portion of the spray nozzle is provided with a suction pipe 123 from block 184 at station 185, if this has not already been done. Then, the assembly set thus made is sent to the positioning station 190 through the buffer 187. A test tube 146 with the biasing means 116 executed at the same time is fed to the casting line from block 186. All subsequent operations correspond to the operations described with respect to the first embodiment and are shown in FIG. 12 . But it is also possible to “charge” the dosing device by filling the pump with a certain amount of liquid taken from the tank. For this, the pump piston is pushed inward before assembling the metering device and the container, and then pushed out during or after assembly, thereby drawing liquid from the container into the pump. The dosing device is now ready for use.

In accordance with another embodiment of the present invention, which can also be used for conventional bottles with a threaded neck, some elements of the spray nozzle are pre-assembled or performed at the same time not with the neck of the container, but with a separate ring 172 (Fig. 23). This ring 172 can then be attached to the neck of a conventional bottle 173 (FIG. 24). Although, in this case, the advantage of simplified assembly is lost to some extent, advantages remain regarding the limited number of elements in the spray nozzle.

A device 202 for dispensing a liquid or gel from a container 201 in accordance with another embodiment of the present invention comprises a pump 203, the suction side 204 of which is connected to the container 201 through the suction passage 205, while its discharge side 206 is connected to the stationary spray nozzle 208 through discharge channel 207. In the shown embodiment, the dispensing device 202 is for a gel similar to a cosmetic soap, and the spray nozzle 208 is in the form of an outlet tube.

The pump 203 comprises two adjacent cylinders, a working cylinder 209 and an exhaust cylinder 210. In each of the cylinders 209, 210 there is a piston 211, 212, made with the possibility of movement. The exhaust cylinder 210 comprises a protrusion 236 for deforming the piston 212 at the end of its stroke, thereby creating an exhaust clearance. Both pistons are actuated by functional means 213, in this case, by means of a pushing member which is moved up and down. In this embodiment, both pistons are rigidly connected, and even made integrally, with the functional element 213.

Functional element 213 is configured to move up and down between the idle position and the discharge position. From this pressure position, the pushing element returns to its inoperative position after the pressure is exerted on it with the help of the return means 214, which in this embodiment is also made by two combined bending and torsion springs 215, made integral with the capacity 201.

Between the pump 203 and the outlet nozzle 208, a precompression system 216 is provided. This pre-compression system comprises a diaphragm 217 forming a portion of the sleeve 218 made in the chamber 220, in which the shut-off valve 219 is arranged to move, the sleeve 218 is attached to the chamber 220 by a latch 237, forming part of the cup-shaped portion 230, which is integral with the capacity 201 .

The pump 203, the chamber 220 of the pre-compression system and part of the suction and discharge lines 205, 207 are made as a continuous casting element 231, which is placed in the bowl-shaped part 230. For this, the element 223 has two mounting tabs 232, which are included in the slots 233, made in cup-shaped portion 230. Thus, the number of individual elements is reduced and assembly is simplified. Possible leakage problems are also minimized.

The dispensing device 202 also contains a blocking means 221, due to which it is possible to eliminate or at least notice the fact of unauthorized use of the device 202. In the first embodiment of the device 202, this blocking means consists of two brittle protrusions 222, which are made in the way of the functional element 213 and are made at the same time with the exhaust pipe 208. The protrusions are made on the grip 23, which the user can manipulate in order to divert this grip from the path of the functional element and tear it into Tate which the push member 13 can be pressed down and the pump 3 is able to act. Since the protrusions 222 must be torn off before use, therefore any (possibly unauthorized) use will always be immediately noticeable.

It is also possible to perform a blocking means 21 or brittle protrusions 22 at the same time with the functional element 13 (Fig.30). In this case, the exhaust nozzle 208 can be made integral with the pressure passage 207, while the number of elements can be reduced even more.

According to another embodiment of the present invention (Fig. 35), the locking means 221 is formed by a cap 224 that is pivotally connected to the pushing member 213 (Fig. 37) and which locks the outlet nozzle and enters a correspondingly shaped recess 225, as a result of which the pushing element 213 snaps fixedly. This embodiment can be easily combined with an outlet nozzle 228, which is designed as a spray or spray element (Fig. 36) and which is made using a cylindrical sleeve 226 having a very small metering hole 227.

According to yet another embodiment (FIG. 44), the return means 214 comprises four bend springs 215 having inclined engagement surfaces 234. The pushing member 213 according to this embodiment has corresponding inclined surfaces 235 cooperating with the springs 215. When the pushing member 213 goes down during the internal compression stroke, the springs 215 are bent inward using the inclined surfaces 235 moving downward. When the pushing member 213 is released, the springs 215 are folded back, causing the pushing member 213 and piston 211 to move up again. The remaining elements of this embodiment correspond to the elements of the previous embodiment, and are not described in detail here.

A device 302 for dispensing a quantity of fluid from a container 301 according to an alternative embodiment of the present invention (Fig. 38) comprises a metering chamber 303, at least a side wall 306 of which is integral with the container 301. A metering element 304 is provided in the metering chamber 303, which communicates with the interior of the container by means of an immersion tube 316, which is placed on the underside 323 of the metering element 304 and extends close to the bottom 318 of the container 301. The metering element 304 is attached to the disk-shaped element 3 07 or is integral with this disk-shaped element 307, which functions as the bottom of the metering chamber 303. This disk-shaped element 307 has a periphery skirt 308 with which it can enter the tapering neck 321 between the container 301 and the metering chamber 303. The disk-shaped element 307 also has a longitudinal groove 326, which is intended to be positioned around a longitudinal rib 328 extending into the metering chamber 303, in order to thereby fix the disk-shaped element in the metering chamber 303, to exclude the possibility spine rotation of this element. The second element 305 is rotatably included in the metering chamber 304. This second element 305 is attached to the cover 311 or is integral with this cover 311, which locks the metering chamber 303 from above, and is rotatable relative to the metering chamber 303. The cover 311 can be attached, for example, using a snap connection 324, 325, to the wall 6 of the metering chamber 303.

In the cylindrical housing 309 of the metering element, several outlets 310 are distributed around the periphery at different heights. A similar cylindrical second element 305 has a channel 320, which is made in the form of a recess in the cylindrical wall 322 and which can be combined with one of the outlets 310 of the metering element 304 by rotating this element 305 relative to the metering element 304. In the position shown in Fig. 39 and 40, the channel 320 of the second element 305 is not aligned with one of the outlets 310 of the metering element 4, as a result of which there is no fluid connection between the interior of the container 301 and the metering chamber 303. The cover 311 is made in the shown embodiment so that in this position the triangular protruding part 313 of the cover 311 interacts in a sealing manner with the outlet or drain 312 of the metering chamber 303. Thus, the possibility of leakage is completely eliminated. An outlet 314 is also provided in the lid 311, which in the open position of the metering device 302 allows air to enter the metering chamber 303 when it becomes empty, but which in the shown closed position is also closed by a cam 315 formed in the upper edge of the rib 328 protruding into metering chamber 303.

Dosing device 302 operates as follows.

When, starting from the closed position shown in Figs. 39 and 40, the lid 311 with the second element 305 is rotated, the metering element 304 is prevented from turning by its groove 326 and ribs 328, while the channel 320 of this second element 305 can be combined with one of outlets 310 of the metering element 304, whereby a fluid communication is established between the container 301 and the metering chamber 303. The implementation of this position is indicated by the reference number 317 on the outer wall 306 of the metering chamber 303, and in the corresponding position, this number is precisely aligned with the triangular locking part 313 of the cover 311. If the container 301 is squeezed in this position, the liquid will move through the immersion tube 316 through the opening 319 in the lower part of the metering chamber 303 into the metering element 304 and then will pass through the channel 320 and the corresponding outlet 310 into the metering chamber 303.

The container 301 needs to be compressed until the liquid level in the metering chamber 303 is in any case higher than the corresponding outlet 310. Upon termination of the compressive force exerted on the container 301, the liquid will be pulled back as a result of the prevailing vacuum at that time from the metering chamber 303 through the outlet 310 and channel 320 into the immersion tube 316 and finally into the container 301. This reverse suction occurs when the outlet 310 is below the surface of the liquid. When the liquid level in the metering chamber 303 reaches the top of the outlet 310, the air will be drawn inward, after which the flow of liquid from the metering chamber 303 to the container 301 will stop. At this point, a precisely defined amount of liquid will remain behind the metering chamber 303, which can then exit through the drain 312.

As indicated above, the container 301 and the metering chamber 303 are performed at the same time. After the container 301 is made and filled with liquid, other elements can be inserted or fixedly latched into the container 301 and the metering chamber 303, after which the container 301 with the metering device is ready for use.

Although the invention is described with reference to several possible embodiments, it will be clear to those skilled in the art that many changes can be made therein. In particular, novelty and inventive features of the characteristics of the metering devices, which do not relate directly to the implementation of part of the metering device with a capacity, can be applied with the same effect with conventional, individually made metering devices. Therefore, the scope of this invention is determined only by the attached claims.

Claims (45)

1. A metering device connected to a container for dispensing a fluid, comprising at least one opening and at least one locking element cooperating with the opening and configured to move between a position closing the opening and a position leaving the hole is open, while at least a portion of the metering device is previously made on the neck of the container, and the rest of the metering device is connected to it, characterized in that the portion of the metering device, p edvaritelno performed on the neck comprises means for fixedly retaining the locking member, at least in one of its positions. 2. The metering device according to claim 1, characterized in that the portion of the metering device previously made on the neck is made integral with the neck. 3. The dosing device according to claim 1 or 2, characterized in that the neck is made integral with the container. 4. The metering device according to any one of the preceding paragraphs, characterized in that the portion of the metering device, made on the neck, contains means for shifting the locking element in one of its positions. 5. The metering device according to claim 4, characterized in that the biasing means comprises at least one spring. 6. A metering device according to any one of the preceding paragraphs, characterized in that at least one pump is made between the container and the hole, the pump having a suction side and a discharge side, and the metering device includes a movable means connected to the pump for its operation , means connected to the suction side of the pump for supplying fluid from the container, and at least one outlet nozzle connected to the discharge side of the pump, a portion of the dose preformed on the container uyuschego device comprises at least part of the functional means. 7. The dosing device according to claim 6, characterized in that the pump is a piston pump connected to means for displacing it into an inoperative position, while the means for displacing the piston is previously made on the tank. 8. The dosing device according to claim 7, characterized in that the piston displacement means comprises at least one spring. 9. The metering device of claim 8, wherein the spring is a bending and / or torsion spring. 10. A metering device according to any one of claims 6 to 9, characterized in that the piston displacement means is adapted to interact with the functional means of the pump. 11. Dosing device according to claim 10, characterized in that the functional means is connected to the piston in such a way as to be fixed under the influence of tension or compression. 12. Dosing device according to claim 11, characterized in that the functional means is latched onto the piston. 13. A dosing device according to any one of claims 6-12, characterized in that the pump has a housing with which the functional means is movably connected. 14. The dosing device according to item 13, wherein the functional means comprises a starting device pivotally latched onto the pump housing. 15. Dosing device according to any one of claims 6 to 11, characterized in that the pump comprises a working cylinder and an exhaust cylinder located next to it, and the functional means is designed to displace the pistons in these cylinders synchronously. 16. The dosing device according to clause 15, wherein the functional means comprises a pushing element, and each piston is made integral with the pushing element. 17. The dispensing device according to claim 15 or 16, characterized in that it comprises means made in the exhaust cylinder for deforming the piston moved therein. 18. A dosing device according to any one of claims 6 to 17, characterized in that it contains a blocking means that interacts with the functional means, while the blocking means contains at least one brittle protrusion made in the way of the functional means. 19. The metering device according to claim 18, wherein each brittle protrusion is connected to an outlet nozzle. 20. The dispensing device according to claim 19, characterized in that the locking means comprises a lid covering the outlet nozzle. 21. Dosing device according to any one of claims 6 to 20, characterized in that it comprises a pre-compression system located between the pump and the outlet nozzle. 22. The dosing device according to item 21, wherein the pump, the pre-compression system and part of the passages connecting the pump to the tank and / or exhaust nozzle, are made at the same time. 23. A metering device according to any one of the preceding paragraphs, characterized in that the rest of the metering device is connected by means of a latch connected to the neck of the container or to a part of the metering device previously made on it. 24. The metering device according to claim 1, characterized in that a portion of the metering and / or filling nozzle previously made on the neck limits the metering chamber, while the metering and / or filling nozzle comprises a movable metering element extending into the metering chamber. 25. The metering device according to paragraph 24, wherein each feed and metering element comprises a substantially cylindrical side wall. 26. The metering device according to paragraphs 24 and 25, characterized in that the feed element has an axial channel made in the form of a recess in its side wall, and the metering element contains many outlet openings located at intervals in the peripheral and axial directions. 27. Dosing device according to any one of paragraphs.24-26, characterized in that the dosing element is attached to the dosing chamber, and the feeding element enters, with the possibility of rotation, into the dosing chamber. 28. The metering device according to item 27, wherein the metering element is installed at the bottom of the metering chamber. 29. The metering device according to claim 28, wherein the metering element is integral with the bottom of the metering chamber. 30. Dosing device according to any one of paragraphs.24-29, characterized in that the feeding element is connected to a cover at least partially covering the metering chamber. 31. The dispensing device according to claim 30, wherein the feeding element is integral with the lid. 32. The metering device according to claim 30 or 31, characterized in that the metering chamber has at least one outlet, and the lid has a means for closing it. 33. Dosing device according to any one of paragraphs.30-32, characterized in that at least one outlet is made in the lid. 34. The dosing device according to p. 33, characterized in that it contains means interacting with the lid, for closing each outlet. 35. The metering device according to any one of the preceding paragraphs, characterized in that the container and part of the metering device, previously made in it, pre-formed by casting. 36. The dosing device according to clause 35, wherein the container is performed by blow molding to the final form after preliminary execution. 37. The node (neck) of the container connected to the metering device, characterized in that the metering device is made according to any one of the preceding paragraphs. 38. Capacity for use in the node, characterized in that the node is made according to clause 37. 39. A method of manufacturing and filling a fluid container with a metering device, comprising the following operations: - perform capacity - pre-perform part of the metering device on its neck, - perform the rest of the metering device, - fill the container with fluid, and - close the container by connecting the rest of the metering device with it, characterized in that the container is preliminarily carried out by injection molding and then by means of pneumoforming it is given its final shape before filling. 40. The method according to § 39, characterized in that the portion of the metering device, previously made on the neck, perform at the same time and simultaneously with it. 41. The method according to § 39 or 40, characterized in that the neck is performed at the same time and simultaneously with the tank. 42. The method according to any of claims 39-41, wherein the container is made of elastically deformable thermoplastic plastic. 43. The method according to any one of paragraphs 39-42, characterized in that the rest of the metering device is connected using a snap connection with the neck of the container or part of the metering device previously made on it. 44. The method according to any one of paragraphs 39-43, characterized in that the container is filled in a suspended position. 45. The method according to any of paragraphs 39-44, characterized in that the rest of the metering device is performed with a pump having a bias element, which is arranged to move between the first and second positions, while the biased element is moved to its second position before closing containers and move to their first position after closing the container, to ensure that the fluid is drawn into the pump.

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