RU2494940C1 - Closure device - Google Patents

Abstract

FIELD: packaging industry.

SUBSTANCE: invention relates to closure devices with dispensers for bottles and can be used for packaging of valuable beverages. The device comprises the main housing located along the longitudinal axis, a working element mounted rigidly on the main housing outside of it in the axial direction and with the ability to rotate relative to the main housing, a dispenser connected to the working element by the screw joint with the ability of its axial movement along the longitudinal axis when rotation of the working element relative to the main housing, the main housing is made with an internal cavity along the longitudinal axis of the device which is bounded by its side inner wall with the guide section with the ability of contact with it of the dispenser wall, in the inner cavity of the main housing an inlet is made, the dispenser is made of three concentrically arranged cylindrical walls with the ability of forming the annular channel outlet for fluid at the open closure device with the outlet side opening in the form of an annular slit, the side outer cylindrical wall of the dispenser with a thread is provided with openings for air passage, located along the perimetre of its upper part below the annular slit, and the lower part of the middle wall of the dispenser is provided with grooves of thickness less than the thickness of this wall.

EFFECT: device enables to increase the slope of the bottle when filling the liquid.

8 dwg

Description

The invention relates to closures with dispensers for bottles and can be used to seal valuable drinks and liquids for other purposes.

A closure device is known, which is made in the form of a stopper with a dispenser for a bottle, comprising a main body located along the longitudinal axis, rigidly connected to the neck of the bottle to ensure its tightness, a working element mounted on the main body outside it, rigidly in the axial direction and rotatable relative to the main body, the dispenser connected to the working element by a threaded connection with the possibility of its axial movement along the longitudinal axis during rotation of the working element relative the main body (see RU 2369543 Capping device with dispenser, IPC B65D 47/24, B65D 49/04, published 03/10/2009.).

The main body has a tubular configuration and is characterized by the presence of an internal cavity along the longitudinal axis of the device, which is limited by its lateral inner wall with a guide section with which the metering wall contacts. The side wall of the main body with the guide portion is provided with an expanding portion of a generally cylindrical inner diameter larger than the diameter of the guide portion. The transition section is made in the form of an inclined plane and ensures that the remaining liquid is drained back into the bottle when it is returned to the vertical position. An inlet for pouring liquid is made in the inner cavity.

The working element is installed outside the closure with a radial clearance relative to the main body, and is equipped with a cover that covers the upper part of the tubular body. The cover of the tubular body is connected around the perimeter with the upper edge of the tubular body using one or more connecting elements - jumpers radially spaced and separated by slots.

The dispenser is made of three concentric cylindrical walls: lateral outer, middle and inner. The outer surface of the lateral outer wall of the dispenser is provided with a threaded portion interacting with a threaded portion of the inner surface of the working element for telescoping the dispenser with it. The lateral outer wall and the middle cylindrical wall of the dispenser form an intermediate cavity of an annular configuration. The middle and inner walls of the dispenser, when the dispenser is raised upward, with the capping device open, form an annular channel that exits the liquid with an outlet side opening located radially relative to the longitudinal axis. The side hole consists of an annular slot in the hollow body.

The walls of the outlet channel are bent towards the outlet. The middle wall of the dispenser is located in the annular cavity of the main body, located coaxially with its inner cavity and defines the zone of movement of the dispenser. The rotation of the working element allows the dispenser to move relative to the main body from the closed position, in which the dispenser interacts with the main body, in an extended open position, in which the dispenser is at a certain predetermined distance from the main body. The consequence of the axial movement of the dispenser relative to the main body is the opening or closing of the passage formed between the liquid outlet channel and the internal cavity of the main body.

Once the dispenser is in the extended position, the contents of the bottle can be poured through an opening in the bottom of the cavity by tilting the bottle.

The design is a single integral connection, eliminating the ingress of its fragments into the environment when opening the closure device. The design prevents re-filling of the bottle and allows the liquid to flow out of the outlet channel in any tilt direction to eliminate the need to tilt the bottle only towards the side outlet. The design provides an optimal closing function, since it eliminates the ingress of dust and other contaminants into the bottle, and ensures the preservation of the quality of the contents. The specified capping device is selected as the closest analogue.

A disadvantage of the described construction is the limitation of the angle of inclination of the bottle at which liquid can be poured out of it, due to the formation of a water seal in the closure when the bottle is tilted to more than 150 degrees relative to the initial position of the bottle in the vertical position. This is due to the fact that at large angles of inclination of the bottle, the fluid flow through the outlet increases, no air enters the internal cavity of the main body of the closure device, and the outflow of fluid is blocked. This limits the capabilities of the closure device and the capabilities of the user. In addition, when the bottle is tilted from 130 to 150 ° relative to the initial position, the liquid flow from the bottle spills, “chokes”, forms spray of the drink, moisturizing the device’s zones adjacent to the liquid passageway.

The objective of the invention is to expand the design capabilities of the capping device, removing restrictions on user actions by making it possible to increase the tilt of the bottle when dispensing liquid. The technical result in this case is to reduce the area of operation of the hydraulic lock, ensuring air circulation in the cavity of the closure device when pouring liquid in a wider range of angles of inclination of the bottle, eliminating the spraying of liquid both inside the device and outside it when pouring liquid.

Another objective is to expand the range of closures for bottles containing valuable liquids.

The problem is solved and the technical result is achieved by the design of the closure device, including, like the prototype, the main body located along the longitudinal axis, rigidly connected to the neck of the bottle, the working element mounted on the main body outside it, rigidly in the axial direction and rotatable relative to the main body , a dispenser connected to the working element by a threaded connection with the possibility of its axial movement along the longitudinal axis during rotation of the working element relative to the main about the body.

The main body has a tubular configuration and is characterized by the presence of an internal cavity along the longitudinal axis of the device, which is limited by its lateral inner wall with a guide section, with the possibility of contact with the dispenser wall. An inlet for pouring liquid is made in the inner cavity of the main body.

The dispenser is made of three concentric cylindrical walls: lateral outer, middle and inner. The outer surface of the lateral outer wall of the dispenser is provided with a threaded portion interacting with a threaded portion of the inner surface of the working element for telescoping the dispenser with it. The lateral outer wall and the middle wall of the dispenser form an intermediate cavity of an annular configuration. The middle and inner walls of the dispenser, when the dispenser is raised upward, with the capping device open, form an annular channel that exits the liquid with an outlet side opening located radially relative to the longitudinal axis. The side opening includes an annular slot in the hollow body.

The walls of the outlet channel are bent towards the outlet. The middle wall of the dispenser is located in the annular cavity of the main body, which is made coaxially with its inner cavity and defines the zone of movement of the dispenser. The dispenser is installed with the possibility of its interaction with the main body with the provision of its movement relative to the main body from the closed position to the extended open position, in which the dispenser is at a certain predetermined distance from the main body and with the opening or closing of the passage between the internal cavity of the main body and the exit for fluid channel.

The difference between the proposed design from the prototype is the following. The lateral outer cylindrical wall of the dispenser with a thread is provided with openings for the passage of air located along the perimeter of its upper part below the annular slot of the outlet. The lower part of the middle wall of the dispenser is equipped with grooves made on the side of the guide as a zone of sinking of this wall, i.e., a thickness less than the thickness of this wall, the geometric dimensions of which are determined by engineering calculations.

Figure 1 shows a longitudinal section of a bottle equipped with a closure device in the closed position, Figure 2 shows a longitudinal section of a bottle in the open position of the device, Figure 3 shows the main body, Figs 4a, 4b are views of the lower part of the main body, Fig. .5 - working element of the capping device, Fig.6 is a perspective view of the dispenser of the capping device, Fig.7 is an axial section of the dispenser.

As can be seen from the drawings, the capping device comprises a main body 3 located along the axis 1 of the bottle 2, rigidly connected to the neck of the bottle 2, a working element 4, mounted on the main body 3 rigidly in the axial direction, rotatably relative to the main body 3, and a dispenser 5 associated with the working element 4 by means of a threaded connection and with the possibility of axial movement during rotation of the working element 4 relative to the main body 3 along the longitudinal axis 1. The main body 3 has a section 6, designed for fastening to bottle neck 7 bottle 2, and a guide section 8, which in the axial direction is a continuation of section 6 and is designed to interact with dispenser 5. Sections 6 and 8 have annular cavities 10 and 12, respectively, concentrically located along axis 1. Annular cavities 10 and 12 are bounded by respective lateral cylindrical walls located along axis 1 and interconnected by an annular flange 13. In the annular cavity 10 there is a collar 14 of the neck 7 of the bottle 2, and there are sections 15 that provide tightness between the bottle 2 and the main body 3, which excludes the passage of liquid by installing the shoulder 14 in the cavity 10 with an interference fit. The tightness sections 15 are annular sections of one of the surfaces of the cavity 10 in radial contact with the lateral outer surface of the shoulder 14. Section 6 also includes elements 16a for axially securing the main body 3 to the bottle 2 and the elements 16c, providing fastening of the main body 3 to the bottle 2 in the radial direction, determining the axial and radial fixation of the main body 3 to the bottle 2 due to interaction with the corresponding structures active elements 17a and 17b of the neck 7 of the bottle 2. Elements 16a are protrusions in section 6 and are located in accordance with the windows in section 6 at a certain distance from each other. The elements 16a are fixed under the lower surface of the element 17a - under the lower surface of the shoulder 14. The main body 3 is fixed in the axial direction relative to the shoulder 14. Elements 16b, providing fixation in the radial direction, are longitudinal ribs protruding radially inward from the cylindrical wall of the portion 6 of the main body 3. Elements 16B are fixed by means of structural elements 17B - teeth radially spaced and protruding from the neck 7 of the bottle 2, preventing rotation about si 1 of the main body 3 relative to the neck 7.

The main body 3 has a tubular configuration and is characterized by the presence of an internal cavity 20 in the main body 3 along the axis 1, which is limited by the side wall 21 and its extension 21. The side wall 21 ¹ has a guide portion 22 of a generally cylindrical shape and a tapering portion 23 of a generally cylindrical shape and having the inner diameter is less than the diameter of the plot 22; the guiding portion 22 is connected to the tapering portion 23 through a transition portion 24 extending from the portion 22 towards the portion 23.

An inlet 25 is provided in the inner cavity 20, located inside the portion 6 fixed to the neck 7 of the bottle 2. The inlet 25 has a circular shape with a crosshair.

The working element 4 includes a tubular body 30 of a cylindrical configuration mounted externally with a radial clearance relative to a portion 6 of the main body 3 and a cover 31 covering the upper part of the tubular body 30. The lower 32 and upper are made along the length of the tubular body 30 of the working element 4 along its length 33 flanges protruding inward. The lower and upper flanges 34, 35 are made on the outer surface of the main body 3 along its length, interacting with the corresponding flanges 32, 33 of the tubular body 30 of the working element 4, which provide a rigid fastening of the working element 4 on the main body 3 in the axial direction. The cover 31 of the tubular body 30 is connected around the perimeter with the upper edge 36 of the tubular body 30 using one or more connecting elements 37 - jumpers radially spaced and separated by slots 38. The cover 31 has a neck 39 protruding into the body 30.

The dispenser 5 includes a hollow body 40 located along the axis 1 and bounded by a lateral cylindrical wall 41 having an outer side surface 42 with a threaded portion 43 in contact with the threaded portion 44 on the inner surface of the tubular body 30, and an upper end portion 45 located mainly perpendicularly axis 1 and having an annular groove 46, in which the neck 39 of the cover 31 is fitted with an interference fit. The threaded section 44 is made with protrusions 48 (Fig. 5).

The hollow body 40 of the dispenser 5 has in its inner part a channel 51 of an annular configuration (FIG. 2) with an output side opening 52 located radially relative to axis 1. Channel 51 includes an axial section 53 parallel to axis 1 and a radial section 54 ending with an output side hole 52, which includes an annular slot and is defined by the outer side surface 42 of the hollow body 40.

The channel 51 is limited by the inner wall 55 of the dispenser 5, located on the inner side of the channel 51, and the middle wall 56 from the outside; both walls 55, 56 are coaxial with axis 1 and bent towards the outlet 52. Walls 55, 56 are located on the periphery of the channel 51 in the immediate vicinity of the outlet 52 and are connected to each other by ribs 57 (figure 2) located radially relative to the axis 1. Walls 55.56 are located coaxially on the inner side with respect to the outer side wall 41, which is separated from wall 56 by an intermediate cavity 58 of an annular configuration. The wall 56 is located in the annular cavity 12 of the main body 3, which defines the displacement zone of the dispenser 5 and has longitudinal grooves 59 (Fig. 3), interacting with circumferential longitudinal outer protrusions 60 of the wall 56 (Fig. 6) for angular fixing of the dispenser 5 relative to the main body 3. The wall 56 of the dispenser 5 is mounted with the possibility of axial movement relative to the main body 3 while simultaneously fixing in the radial direction, which is achieved by placing the wall 56 in the annular cavity 12. The wall 55 is located on an interference fit (tight fit) in the radial direction inside the guide portion 22 of the cavity 20, while the wall 56 located in the cavity 12 is installed on the outside of the portion 22 coaxially with it, with an interference fit; The contact zones between the wall 55 and section 23, as well as between the wall 56 and section 22, determine the tightness zones 61 and 62, respectively, in the radial direction between the main body 3 and the dispenser 5 in the closed position of the device.

The side wall 21 ¹ as a continuation of the wall 21 of the cavity 20 of the main body 3 is located in the channel 51 and interacts with the walls 55 and 56 of the channel 51, made with the possibility of movement relative to the side wall 21 ¹ while ensuring tightness through the sections 61, 62 in the radial direction in the closed position of the dispenser. The tightness sections 61 and 62 are located between the dispenser 5 and the main body 3, and their location is determined by the contact areas between the side wall 21 ¹ and the walls 55 and 56 of the channel 51, which are specially located on opposite surfaces of the side wall 21 ¹ .

The main body 3 is tightly fixed to the bottle 2, while the working element 4 is connected with the main body 3 in the axial direction and can be rotated relative to it, which implies that the working element 4 is also mounted on the bottle 2. The dispenser 5 has a telescopic connection with the working element 4 through threaded sections 43 and 44 with the possibility of axial movement relative to the main body 3 by rotating the working element 4 relative to the main body 3, the result of which is the opening or closing of the passage 63 (figure 2), between the channel 51 and the internal cavity 20. Since the dispenser 5 has an angular connection with the main body 3 and, therefore, with the bottle 2, the rotation of the working element 4 allows the dispenser 5 to move relative to the main body 3 from the closed position when the dispenser 5 interacts with the main body 3, and the passage 63 between the cavity 20 and the channel 51 is closed by the side wall 21 ¹ , in an extended open position, in which the dispenser 5 is at a certain predetermined distance from the main body 3, and the passage 63 is open (figure 2).

When the bottle 2 with the closure device is opened for the first time, the rotation of the working element 4 relative to the bottle 2 causes the jumpers 37 to break off and the lid 31 is separated from the tubular body 30, but the neck 39 of the dispenser 5, which is in close contact with the walls of the annular groove 46 of the dispenser 5, holds tightly a cover 31 connected to the dispenser 5, avoiding its release into the environment. Jumpers 37 perform the functions of a seal guaranteeing the integrity of the liquid in the bottle 2.

As soon as the dispenser 5 becomes in the extended position, the contents of the bottle can be poured through the hole 25 in the bottom of the cavity 20 by tilting the bottle. The fluid flows through the cavity 20, the open passage 63, the channel 51 to the outlet 52.

The dispenser 5 is provided with openings 64 made around the circumference (around the perimeter) of the upper part of the cylindrical outer side wall 41 of the hollow body 40. These openings 64 are made below the location of the annular channel 54 of the dispenser 5. The cylindrical middle wall 56 of the dispenser 5 is grooved in its lower part 65 as the zones of drowning of this wall, i.e., the thickness is less than the thickness of this wall, the geometric dimensions of the grooves are determined by calculation. In this case, between the grooves 64 and the wall 21 ¹ with the raised dispenser 5, a free passage for air is formed. The grooves 65 are located around the perimeter of the middle cylindrical wall 56 of the dispenser, which, when the device is open (the dispenser 5 is pulled upward), allows air to pass from the openings 64 through the intermediate cavity 58 of the walls 41 and 56 into the cavity 20 of the device, forming an air corridor, providing air circulation and thereby thereby eliminating the formation of a water seal in the closure when the bottle 2 is tilted over a wide range of angles when pouring liquid from it. The grooves 65 are made of such a thickness that liquid is not accessible into the air passage passing through the cavities 58-12, therefore, into areas not intended for the liquid. The free passage of air between the grooves 65 and the wall 21 ^{1 is} smaller than the size of the liquid droplets and is determined by calculation. The tightness of section 2 between the main body 3 and the dispenser 5 in the open position of the device (with the dispenser raised) for air is violated, while leaving it inaccessible to liquid.

The closure device operates as follows.

If necessary, open the bottle by rotating the working element due to the interaction of the threaded sections 43-44, they achieve the rise of the dispenser 5, with which, as an integral part, its walls 55, 56 begin to move. A significant force begins to act on the radial lintels 37 and they are weakened by radial slots 38 between them are torn. The working element 4 remains on the main body 3, the cover 31 - on the dispenser 5, being rigidly fixed to it with the neck 39. The initial opening was carried out, the channel 63 for the liquid is formed (open). Further, by tilting the bottle 2 to an angle of up to 175 ° relative to its initial vertical position, the liquid is poured from the bottle, while the liquid passes the way from the bottle 2, bypassing the hole 25, the cavity 20 of the main body 3, the narrowed section 23, passing further along the annular channel 63 the channel 51, limited by the walls 56, 55 of the dispenser 5, through the annular slot of the outlet 52, limited by the flanges 45. In this case, the air entering through the holes 64 located on the side opposite to the angle of inclination of the bottle 2 passes through the air corridor, min grooves 65, enters through the cavity 58-12 into the cavity 20 of the fluid flow, thereby displacing the fluid poured from the bottle, eliminating the water seal, normalizing the quiet flow of fluid from the bottle without the formation of air bubbles and without spraying it over a wider range of tilt angles with respect to prototype and eliminating the effect of vacuum. The lower the air inlet openings 64 are located on the wall 41 of the dispenser 5, the later the water lock works, the more the angle of inclination of the bottle is possible with a quiet flow of liquid from it, without spraying. After pouring the liquid from the bottle, it is given the initial vertical position with the neck 7 facing up and the rotation of the working case in the opposite direction converts the rotational movement of the working element into the axial movement of the dispenser together with the cap rigidly fixed on it, the dispenser with the wall 55 is lowered to its seat of the tapering section 23, closing the channel 63 for liquid, tightly corking the main body 3. Due to the small size of the gap between the grooves 65 and the wall 21 of the smallest possible droplet size due to the large surface atyazheniya drops of liquid into the air passage does not pass at the time of tilting the bottle 2, or at the time of filling the liquid or at the time of returning the bottle to its original state, allowing passage only air.

Claims (1)

A capping device including a main body located along the longitudinal axis, a working element fixed to the main body outside it rigidly in the axial direction and rotatably relative to the main body, a dispenser connected to the working element by a threaded connection with the possibility of its axial movement along the longitudinal axis during rotation working element relative to the main body, the main body is made with an internal cavity along the longitudinal axis of the device, which is limited by its lateral a morning wall with a guide section with the possibility of contacting the dispenser wall with it, an inlet is made in the inner cavity of the main body, the dispenser is made of three concentric cylindrical walls: the outer side, middle and inner side, the side outer wall and the middle wall of the dispenser form an intermediate cavity of an annular configuration , the middle and inner walls of the dispenser are made with the possibility of forming an annular outlet for liquid channel with an open capping device with one side hole, including an annular slot, characterized in that the lateral outer cylindrical wall of the dispenser with thread is provided with openings for air passage located along the perimeter of its upper part below the annular slot of the outlet, and the lower part of the middle wall of the dispenser is provided with grooves on the side of the guide thickness, smaller thickness of this wall.

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