EP3861974B1 - Capsule closing device for closing two-part capsules - Google Patents

Description

The invention relates to a capsule closing device for closing two-part capsules with the features according to the preamble of claim 1.

Particularly in the pharmaceutical field, but also in the field of food supplements or the like, swallowable capsules are used, in the interior of which active substance preparations or the like are filled. Such capsules are designed in two parts and consist of a lower capsule part and an upper capsule part attached thereto. Common capsule materials are hard gelatine, HPMC (hydroxypropyl methyl cellulose) or the like.

Empty capsules are delivered for filling in a loosely assembled state and fed to a capsule closing device. This comprises a capsule upper part receptacle and a capsule lower part receptacle, with the loosely assembled empty capsule first coming to rest in the capsule upper part receptacle. Proceeding from this, the lower capsule part is pulled out of the upper capsule part, for example by means of a vacuum, and inserted into the lower capsule part receptacle. The capsule bottom part is filled in the capsule bottom part receptacle. After this, the lower capsule part is pressed, for example by means of a stamp, to receive the upper capsule part and is inserted there into the upper capsule part.

In the practical operation of such a capsule closing device, high separating forces are required during the opening of the capsule. Such separating forces are formed by a vacuum acting on the lower part of the capsule. If the lower capsule part has become detached from the upper capsule part, the lower capsule part is conveyed into the lower capsule part receptacle so quickly by the applied, high vacuum that so-called capsule jumping can occur. Capsule jumping occurs when the capsule base hits the capsule base receptacle off-centre and a return pulse pushes the capsule base out of the capsule base receptacle. Capsule jumping of this type can also occur with capsule shells, so that after the capsule base has been separated from the capsule shell, the capsule shell jumps out of the capsule shell receptacle.

Furthermore, with such high separating forces, the capsule bottom of the capsule base can also tear or break when it hits the capsule base receptacle. Since high forces are also required when closing the capsule, the base can be dented or even break by the punch acting on the base of the lower part of the capsule.

From the US 2011/0088355 A1 a capsule filling device with a closing device is known.

The invention is based on the object of further developing a generic capsule closing device in such a way that its operational reliability is increased.

This object is achieved by a capsule closing device having the features of claim 1.

The capsule closing device according to the invention is based on the consideration that the necessary high forces for separating and closing the capsule are based on a lack of pressure equalization. When separating the capsule that supports Capsule shell from along its capsule edge on the support paragraph of the capsule shell recording. The lower part of the capsule is flush with the insertion hole of the upper part of the capsule. Consequently, the capsule cap and the capsule body define one Interior space, the volume of which expands with the downward movement of the capsule base in the direction of the capsule base receptacle. The interior remains at least initially sealed in an essentially airtight manner. Accordingly, a negative pressure forms in the interior space between the upper part of the capsule and the lower part of the capsule, which makes it difficult to separate the capsule.

After a correspondingly long downward movement of the lower capsule part, it leaves the upper capsule part receptacle, as a result of which the interior space formed by the upper capsule part and lower capsule part opens. This is followed by a pressure equalization which, due to the previously created high negative pressure, causes such a high alternating pulse that the capsule shell can be pushed out of the capsule shell receptacle.

In order to reduce the high separating forces and the high alternating impulse, the capsule shell receptacle has at least one ventilation groove on its inside. The ventilation groove extends from the receiving bore to the insertion bore. The capsule shell receptacle preferably has at least two, in particular three, ventilation grooves on its inside. When the capsule is opened, sufficient air can flow through the ventilation groove into the interior space between the upper part and the lower part of the capsule, so that pressure equalization is ensured. There is no or at most only a slight negative pressure in the interior. With an increasing number of venting grooves in the upper part of the capsule, the pressure can be equalized more quickly. The capsule body is easier to separate from the capsule cap. Because of the reduced separating forces, the lower capsule part that is finally detached is sucked into the lower capsule part receptacle with less force, as a result of which capsule cracking or other damage to the capsule can be avoided. By avoiding a high negative pressure, the resulting alternating impulse when the pressure is equalized is also only very small, so that an unintentional ejection of the upper part of the capsule from the upper part of the capsule can be avoided.

The pressure equalization also takes place when the capsule is closed. When the lower capsule part is pushed through the upper capsule part receptacle into the upper capsule part, the volume of the interior space between the lower capsule part and the upper capsule part is reduced. The excess air escapes through the ventilation groove, which avoids overpressure when the capsule is closed. Accordingly, no excess pressure counteracts the closing force on the lower part of the capsule. The forces can be reduced when closing the capsule, so that any damage to the capsule due to excessive closing forces can be avoided.

The receiving bore of the upper part of the capsule preferably extends from a first longitudinal end to a second longitudinal end on the support shoulder, the at least one venting groove running from the insertion bore to the first longitudinal end of the receiving bore. The first longitudinal end of the receiving bore corresponds to an insertion area with an insertion bevel for threading in the capsule. The insertion area tapers in the direction from the first longitudinal end to the second longitudinal end. As a result, the air can flow into the capsule shell receptacle when the capsule is opened or can escape from the capsule shell receptacle when the capsule is closed. This ensures pressure equalization in the capsule shell receptacle, in particular in the interior space between the capsule shell and the capsule shell, with the environment.

The support shoulder of the capsule closing device typically has a peripheral inner edge. In such a case, the at least one ventilation groove advantageously forms an interruption in this inner edge. Accordingly, the interruption of the inner edge is located exactly at the position at which the capsule upper part and the capsule lower part overlap in the closed state. If the lower part of the capsule is pulled out of the upper part of the capsule, the pressure in the interior can be equalized at the earliest possible point in time when the lower part of the capsule and the upper part of the capsule no longer overlap. When closing the capsule, the pressure can equalize take place over as long a period of time as possible until the lower part of the capsule and the upper part of the capsule overlap again and define an airtight interior space.

The capsule closing device preferably comprises a suction device for sucking off dust particles on the capsule. The suction device can preferably be connected to the ventilation groove. As a result, the capsule can be cleaned at an early stage of dust particles which, for example, have settled on the capsule during the filling process or were whirled up during the closing process.

It is preferably provided that the support shoulder is formed by an annular groove in the receiving bore for receiving unwanted filling material. The receiving bore preferably comprises a second longitudinal section adjoining the annular groove and a first longitudinal section adjoining the second longitudinal section. The first longitudinal section of the receiving bore preferably forms a constriction for clamping the upper part of the capsule. The capsule pushed into the receiving bore is held clamped on the capsule upper part by the constriction of the second section. The constriction is designed in such a way that the clamping forces are sufficiently high to prevent the upper part of the capsule from jumping when the capsule is separated and closed, and the capsule can still be ejected intentionally without damaging it.

Provision is advantageously made for the receiving bore to have a clamping diameter at the constriction, the clamping diameter being smaller than a base diameter of the second longitudinal section. The constriction of the receiving bore is formed by this clamping diameter, which is smaller than the base diameter. The base diameter is preferably constant over the entire second longitudinal section. The clamping diameter is advantageously larger than the diameter of the receiving bore on the support shoulder. As a result, the clamping diameter at the constriction is sufficiently small to keep the cap clamped. In addition, the Clamping diameter is still sufficiently large that such strong compression that the capsule upper part slips past the support shoulder into the insertion bore can be avoided. In an analogous manner, the corresponding lower capsule bushing can also have a constriction with a combination of base diameter and clamping diameter. Appropriately, the ratio of the clamping diameter to the base diameter is about 0.97 on the capsule top bushing and about 0.96 on the capsule bottom bushing.

An independent idea that is also inventive consists in providing the aforementioned capsule closing device only with the aforementioned constriction instead of a ventilation groove.

Fig. 1

in einer schematischen, teilweise geschnittenen Seitenansicht eine zweiteilige Kapsel,

Fig. 2

in einer Längsschnittdarstellung eine erfindungsgemäße Kapselverschließeinrichtung,

Fig. 3

in einer Schnittdarstellung die Kapseloberteilaufnahme,

Fig. 4

in einer Draufsicht die Kapseloberteilaufnahme,

Fig. 5

in einer Schnittdarstellung die Kapseloberteilaufnahme mit Verengung und

Fig. 6

in einer Schnittdarstellung die Kapseloberteilaufnahme mit Verengung ohne Entlüftungsnut.

Exemplary embodiments of the invention are explained below with reference to the drawing. Show it:

1

in a schematic, partially sectioned side view, a two-part capsule,

2

in a longitudinal section, a capsule closing device according to the invention,

3

in a sectional view, the capsule shell recording,

4

in a top view, the capsule shell recording,

figure 5

in a sectional view, the capsule shell recording with constriction and

6

in a sectional view, the capsule shell receptacle with constriction without venting groove.

1 shows a schematic, partially sectioned representation of a two-part capsule 20, as used for example in the pharmaceutical sector or in the field of food supplements, and which contains an active ingredient preparation in the filled state. When filled and closed, it is intended to be swallowed by one person. Various materials such as hard gelatine, HPMC or the like come into consideration as the capsule material, which dissolves after swallowing and releases the capsule contents.

The two-part capsule 20 is composed of a capsule shell 21 and a capsule shell 22, wherein the capsule shell 22 with a base nominal diameter du is inserted into the open side of the capsule shell 21 with a larger shell nominal diameter D _O . The upper part 21 of the capsule consists of a conventional design of a hemispherical cap 23 which is adjoined by a cylinder section 24 . The capsule upper part 21 is delimited on its open side by a circumferential capsule edge 25 of the cylinder section 24 . The lower capsule part 22 is constructed analogously to the upper capsule part 21 and consists of a hemispherical cap 26 to which a cylinder section 27 is connected. On its side facing the upper capsule part 21 and inserted there, the lower capsule part 22 is delimited by a circumferential capsule edge 28 of the cylinder section 27, with when the upper capsule part 21 and lower capsule part 22 are plugged together, part of the cylindrical section 27 together with its circumferential capsule edge 28 is inside the cylindrical section 24 of the upper capsule part 21 comes to rest.

2 shows a capsule closing device 1 according to the invention in a longitudinal sectional view, which comprises a capsule upper part receptacle 2 and a capsule lower part receptacle 3 . In the capsule closing device 1 a capsule closing arrangement with a capsule upper part 21 and a capsule lower part 22 of a capsule 20 is arranged.

Empty capsules 20 after 1 are delivered in a state in which the lower capsule parts 22 are loosely inserted into the respectively assigned upper capsule parts 21 . In this state, a single capsule 20 is fed into the capsule closing device 2 introduced from above according to an arrow 12 in such a way that it comes to rest inside the capsule shell receptacle 2 .

The upper capsule part receptacle 2 has a receiving bore 4 for receiving the upper capsule part 21 and transitions in the direction of the lower capsule part receptacle 3 into a coaxially arranged insertion bore 5 . The diameter of the insertion bore 5 is reduced compared to the diameter of the receiving bore 4 so that at the transition between the receiving bore 4 and the insertion bore 5 a circumferential support shoulder 6 is formed. The support shoulder 6 delimits the receiving bore 4 at the bottom and, like the insertion bore 5 , is narrowed in relation to the receiving bore 4 . The capsule 20 is inserted into the capsule shell receptacle 2 according to the arrow 12 in such a way that the capsule shell 21 comes to rest with its cylinder section 24 in the receiving bore 5, while the circumferential capsule edge 25 of the capsule shell 21 rests on the support shoulder 6. The support shoulder 6 has an inner diameter that is reduced compared to the receiving bore 4, through which the lower capsule part 22 can be passed.

Below the capsule shell receptacle 2, the capsule base receptacle 3 is positioned coaxially and includes a receptacle bore 13. The capsule base 22 protruding into the insertion bore 5 is pulled out of the capsule cap 21 into the receptacle bore 13 of the capsule base receptacle 3 in the direction of arrow 12, for example by means of a vacuum or the like it comes to rest with its downward-pointing spherical cap 26 on a shoulder 14 that is reduced in diameter compared to the receiving bore 13 . In this case, the cylinder section 27 of the lower capsule part 22 is supported by the peripheral wall of the receiving bore 14 .

The lower capsule part 22 is filled with the active ingredient preparation, not shown, while it is held in the lower capsule part receptacle 3 . After filling has taken place, the capsule 20 is closed by means of the capsule closing device 1, in that the lower capsule part 21 is pressed upwards through the receiving bore 14 and the insertion bore 5 into the upper capsule part 21, for example by means of a stamp (not shown) in the opposite direction of the arrow 12. In this case, a counterforce is exerted on the upper capsule part 21 in order to fix it spatially in the direction of the arrow 12, for example by means of a stamp, which is also not shown. During the closing process, the circumferential capsule edge 28 of the lower capsule part 22 slides radially inside the circumferential capsule edge 25 of the upper capsule part 21 into its cylinder section 24 .

In 3 is an enlarged sectional view of the capsule shell recording 2 after 2 shown. The receiving bore 4 extends along a longitudinal axis 16 of the capsule shell receptacle 2 from a first longitudinal end 30 to a second longitudinal end 31. The receiving bore 4 can be divided in the direction of arrow 12 into a plurality of sections in the appropriate order, namely the first longitudinal end 30, a longitudinal section 32 and the second longitudinal end 31. The first longitudinal end 30 of the receiving bore 4 is formed by an insertion region 35 with an insertion bevel 36 for threading the capsule 20 in. The insertion area 36 tapers in the direction of the arrow 12 and transitions into the longitudinal section 34 . The longitudinal section 34 extends to the second end 31 of the receiving bore 4, the receiving bore 4 being cylindrical along the longitudinal section 34 and having a constant diameter D ₁ . The second end 31 is formed by a circumferential annular groove 29 on the inside 11 of the capsule shell receptacle 2 . The annular groove 29 serves to accommodate any filling material that has escaped undesirably. A support shoulder 6 is formed on the annular groove 29 , the support shoulder 6 having a shoulder diameter D _A which is smaller than the diameter D ₁ of the receiving bore 4 on the longitudinal section 34 . When the capsule is inserted into the receiving bore 4 , the upper capsule part 21 comes to rest with its capsule edge 25 on the support shoulder 6 . Through the annular groove 29 is prevents the capsule edge 25 of the capsule shell 21 from being pressed radially inwards by the said filling material accumulated on the support shoulder 6 . Adjacent to the support shoulder 6 is the insertion bore 5 , which extends in the direction of the longitudinal axis 16 of the capsule shell receptacle 2 up to the end 37 of the bore. At the end 37 of the bore, the insertion bore 5 widens again like a funnel in the direction of the arrow 12, as a result of which the threading of the lower capsule part 22 into the insertion bore 5 is promoted after the filling process.

As in the Figures 2 to 4 shown, a plurality of ventilation grooves 9 are formed on the capsule upper part receptacle 2 . The preferred embodiment of the capsule shell receptacle 2 has three ventilation grooves 9 ( 4 ). However, the formation of a single ventilation groove 9 can already be expedient.

When the capsule 20 is separated, the upper capsule part 21 lies flush with its capsule edge 25 on the inside 11 of the receiving bore 4 . If the lower capsule part 22 is pulled out of the upper capsule part 22 , the capsule edge 28 of the lower capsule part 22 is also flush with the inside 11 of the insertion bore 5 . The upper capsule part 21 and lower capsule part 22 delimit an interior space 15 . The ventilation groove 9 enables an exchange of air between the interior space 15 and the environment outside of the upper capsule part receptacle 2 . Consequently, when the capsule 20 is separated and closed, a pressure equalization takes place, so that an underpressure or overpressure present in the interior space 15 can be avoided.

The ventilation groove 9 is formed on the inside 11 of the capsule shell receptacle 2 . As in 3 shown, the venting groove 9 runs from the insertion bore 5 to the receiving bore 4. In the exemplary embodiment, the venting groove 9 extends from the insertion bore 5 to the first longitudinal end 30 of the receiving bore 4. Accordingly, the venting groove 9 runs to the insertion area 35 of the receiving bore 4. Since the insertion area 35 has the insertion bevel 36, the capsule shell is 21 in Insertion area 35 not on the inside 11. Thus, the ventilation groove 9 in the insertion area 35 is not closed by the capsule 20, as a result of which the pressure can be equalized with the environment. In an alternative embodiment of the capsule closing device 1, it can even be sufficient for effective pressure equalization if the venting groove 9 extends only into the longitudinal section 34. This applies when the longitudinal section 34 of the receiving bore 4 extends over a particularly wide longitudinal area in the direction of the longitudinal axis 16 . The venting groove 9 should then extend at least so far into the receiving bore 4 that the end 38 of the venting groove 9 facing away from the supporting shoulder 6 is at a distance a from the supporting shoulder 6 that corresponds at least to the diameter D ₁ of the receiving bore 4 on the longitudinal section 34.

As in 3 shown, in the preferred exemplary embodiment, the venting groove 9 runs through the support shoulder 6 and thereby forms an interruption 8 in the essentially circumferential inner edge 7 of the support shoulder 8. With the interruption 8 in the inner edge 7 of the support shoulder 6, the capsule edge 25 of the capsule upper part 21 is not in airtight contact with the Support paragraph 6, which ensures the earliest possible pressure equalization.

In the 4 is the capsule shell receptacle 2 according to the embodiment of FIG 2 shown in a plan view. The ventilation grooves 9 are distributed in the circumferential direction of the longitudinal axis 16 at a uniform angular spacing. Accordingly, in the exemplary embodiment 4 the angular spacing of the three ventilation grooves 9 is 120°. It can also be expedient to form the venting grooves 9 on the capsule shell receptacle 2 at an uneven angular spacing in the circumferential direction of the longitudinal axis 16 .

As in 4 shown, the ventilation groove 9 extends in the circumferential direction of the longitudinal axis 16 over a width which corresponds to an angular range α of at least 15°, preferably at least 30°, advantageously approximately over 40°. The ventilation groove 9 has a depth b measured radially to the longitudinal axis 16 , which corresponds to a range of 2 to 10% of the diameter D ₁ of the receiving bore 4 on the longitudinal section 34 . In the exemplary embodiment, the depth b of the ventilation groove 9 is approximately 6% of the diameter D ₁ . The ventilation grooves 9 are preferably of the same design. The ventilation grooves 9 can be produced, for example, by drilling, milling, or eroding.

In figure 5 a further embodiment variant of the capsule closing device 1 is shown, which differs from the exemplary embodiment 3 differs only in an additional constriction 40 for clamping the capsule upper part 21 in the receiving bore 4. The longitudinal section 34 of the receiving bore 4 shown in the previous embodiment is divided into a first longitudinal section 32 and a second longitudinal section 33 adjoining it. The first longitudinal section 32 thus runs from the first longitudinal end 30 to the second longitudinal section 33, with the second longitudinal section 33 at the second longitudinal end 31 adjacent.

As in figure 5 shown, the receiving bore 4 includes a constriction 40 for clamping the capsule upper part 21. The constriction 40 is formed in the first longitudinal section 32 of the receiving bore 4. The constriction 40 is formed by reducing the cross section of the receiving bore 4 . The first longitudinal section 32 has a clamping diameter D _K that is smaller than a base diameter D _G of the second longitudinal section 33. The clamping diameter D _K corresponds to the smallest diameter in the first longitudinal section 32. The receiving bore 4 is cylindrical in the second longitudinal section 33. Therefore, the base diameter D _G of the second longitudinal section 33 is constant. In an alternative embodiment, it can be expedient not to construct the second longitudinal section in a cylindrical manner. In such a case the clamping diameter D _K of the first longitudinal section 34 is smaller than each diameter in the second longitudinal section 33. The clamping diameter D _K at the constriction 40 is less than the outside diameter of the capsule cap 21, so that the capsule cap 21 is clamped by the constriction 40. It is advantageous if the constriction 40, as shown in the exemplary embodiment, is formed near the first longitudinal end 30 of the receiving bore 4, since compression of the capsule edge 25 of the capsule upper part 21 is avoided. This is necessary in order to ensure reliable support of the capsule shell 21 on the support shoulder 6 and to secure the capsule shell 21 against slipping through the insertion bore 5 . Therefore, the constriction 40 is on the upper longitudinal half, i.e. the longitudinal half of the receiving bore 4 facing away from the supporting shoulder 6. In the preferred embodiment, the clamping diameter D _K is larger than the diameter D _A of the receiving bore 4 on the supporting shoulder 6.

In 6 a further embodiment is shown in which only one constriction 40 without a ventilation groove 9 is formed.

In a further development, the capsule closing device 1 according to the invention can have an in 2 include only schematically indicated suction device 17. The suction device 17 is connected to the one or more ventilation grooves 9 and is primarily used to suck off dust particles adhering to the capsule 20 . To clean the capsule 20, the suction device 17 is only switched on when the capsule 20 is already closed again after the filling process. This prevents the capsule contents from being sucked out of the lower capsule part 3 by the suction device 17 . In addition, the suction device 17 can also be used to clean the capsule shell receptacle 2 of dust particles that settle on the inside 11 of the capsule shell receptacle 2, for example.

Claims (10)

1. Capsule closing device for closing two-part capsules (20) having in each case one capsule upper part (21) and one capsule lower part (22);

   wherein the capsule closing device (1) comprises a capsule upper part receptacle (2) and a capsule lower part receptacle (3);

   wherein the capsule upper part receptacle (2) has a receptacle bore (4) and an introduction bore (5) which is disposed so as to be coaxial with the receptacle bore (4); and

   wherein the capsule upper part receptacle (2) on the inside (11) thereof, between the receptacle bore (4) and the introduction bore (5), has a support ledge (6) for supporting the capsule upper part (21),

   characterized in that

   the capsule upper part receptacle (2) on the inside (11) thereof has at least one ventilation groove (9), wherein the ventilation groove (9) extends from the receptacle bore (4) to the introduction bore (5).
2. Capsule closing device according to Claim 1,
   characterized in that the capsule upper part receptacle (2) on the inside (11) thereof has at least two, in particular three, ventilation grooves (9).
3. Capsule closing device according to Claim 1 or 2,
   characterized in that the receptacle bore (4) of the capsule upper part extends from a first longitudinal end (30) to a second longitudinal end (31) on the support ledge (6), wherein the at least one ventilation groove (9) runs to the first longitudinal end (30) of the receptacle bore (4) of the capsule upper part receptacle (2).
4. Capsule closing device according to one of Claims 1 to 3,
   characterized in that the support ledge (6) has an encircling inner edge (7), and the at least one ventilation groove (9) forms an interruption (8) of the inner edge (7).
5. Capsule closing device according to one of Claims 1 to 4,
   characterized in that the capsule closing device (1) comprises a suction device (17) for suctioning dust particles on the capsule (20).
6. Capsule closing device according to one of Claims 1 to 5,
   characterized in that the support ledge is formed by an annular groove (29) which, for receiving undesirable filling material, is formed in the receptacle bore (4).
7. Capsule closing device according to Claim 6,
   wherein the receptacle bore (4) comprises a second longitudinal portion (33) adjacent to the annular groove (29), and a first longitudinal portion (32) adjacent to the second longitudinal portion (33), wherein the first longitudinal portion (32) of the receptacle bore (4) forms a constriction (40) for clamping the capsule upper part (21).
8. Capsule closing device according to Claim 7,
   characterized in that the receptacle bore (4) on the constriction (40) has a clamping diameter (D_K), wherein the clamping diameter (D_K) is smaller than a basic diameter (D_G) of the second longitudinal portion (33).
9. Capsule closing device according to Claim 7 or 8,
   characterized in that the basic diameter (D_G) is constant across the entire second longitudinal portion (33).
10. Capsule closing device according to Claim 6,
    characterized in that the clamping diameter (D_K) is larger than the diameter (D_A) of the receptacle bore (4) at the support ledge (6).

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