NL2028943A - Pneumatic tube duct for disinfecting a pipeline system of a pneumatic tube installation - Google Patents

Abstract

A pneumatic dispatch tube for detecting a pipeline system of a pneumatic dispatch system has a tube head (21, 22) each with a sliding ring (5, 5') at its two ends, UVC light sources ( 8, 8') are provided. According to the invention, a coarse brush (3) is provided on a tubular head (21) in addition to the sliding ring (5), which brush (3) is located on the side of the sliding ring (5) remote from the other tubular head (22), whereby a wiper lip (4) is provided between the coarse brush (3) and the sliding ring (5). In this way, contaminants are removed before the tube of the pipeline system is disinfected by means of the UVC light sources (8, 8'). Alternatively to or in addition to the UVC light sources (8, 8') a manifold (18) may also be provided for spraying a disinfectant, wherein a pump (13) for pumping the disinfectant from a storage reservoir ( 14) to the manifold (18). In that case, the coarse brush (3) is provided on the tubular head (2 1) located opposite the manifold (18), in addition to the sliding ring (5).

Description

P130851NL00 Title: Pneumatic tube duct for disinfecting a pipeline system of a pneumatic tube installation The present invention relates to a pneumatic tube duct for disinfecting a pneumatic tube system of a pneumatic dispatch installation, wherein the tube each has a tube head with a sliding ring at both ends thereof, in which case between the sliding rings are provided with UVC light sources. The invention furthermore relates to a pneumatic dispatch tube for disinfecting a pipeline system of a pneumatic dispatch installation, wherein the tube each has a tube head with a sliding ring at its two ends, wherein a nozzle for spraying a disinfectant is provided in a tube head. and wherein a pump for pumping the disinfectant from a storage reservoir to the manifold is provided.

These two pneumatic post tubes have in common that they have means for disinfecting a pipeline system, i.e. they can disinfect a transport tube along the inside during a movement.

A pneumatic dispatch tube of the aforementioned kind is known from document US 2015/0246152 A1, in particular figure 7. The pneumatic dispatch tube is guided through a tube while the UVC light sources are switched on, so that the surface of the tube is covered by the UVC radiation. is disinfected. A drawback here is that in the case of coarser contaminations, such as these can arise for instance as a result of dried blood, which can happen when a tube in a pneumatic post tube containing a blood sample breaks and the blood runs away, only the surface of the contamination is disinfected. When the pneumatic dispatch installation is subsequently put back into operation, the normal pneumatic dispatch tubes slowly but surely scrape the surface of the dried blood, until deeper layers appear that have not been disinfected.

A pneumatic post tube of the second type 1s is known from document DE 102016215447 B3. With a view to disinfecting a pipeline system, this pneumatic dispatch tube can spray a disinfectant. According to Fig. 3, the disinfectant is sprayed from the front socket head in the direction of displacement, and the sliding ring on the rear socket head is designed as a coarse brush which is mechanically driven. This solution has the disadvantage that the disinfectant is wiped off by the front sliding ring, so that it has only a very short chance to act, and that contaminants that can be removed by the coarse brush at the rear end of the pneumatic dispatch tube from the internal wall of the tube, remain in the tube and are unlikely to come into contact with the disinfectant at all, as the disinfectant has already been wiped off through the front slide ring.

It is therefore an object of the present invention to provide a pneumatic post tube of the above-mentioned type, which nevertheless enables reliable disinfection with a single pass.

This object is achieved by the present invention by means of a pneumatic dispatch tube of the above-mentioned type, wherein the pneumatic dispatch tube comprises on a tube head, in addition to the sliding ring, a coarse brush which is provided on the side of the sliding ring remote from the other tube head, and wherein a wiper lip is provided between the coarse brush and the sliding ring.

This object is further achieved by the present invention by means of a pneumatic dispatch tube of the above-mentioned second type, wherein a coarse brush is provided on the tube head located opposite the manifold, in addition to the sliding ring, which brush is arranged on the side facing away from the tube head with the manifold. side of the sliding ring, and wherein a wiper lip is provided between the coarse brush and the sliding ring.

These two solutions have in common that, viewed in the direction of displacement of the pneumatic post tube, a coarse brush is provided at the front, behind which a wiper lip is arranged. In contrast to the aforementioned document DE 102016215447 B3, the coarse brush is thus arranged completely at the front in the direction of displacement, and behind it there is a wiper lip which pushes the removed impurities in front of it. As a result, the light from the UVC light sources falls on the mechanically already cleaned inner wall of the pipe, or the manifold sprays the disinfectant onto the mechanically already cleaned inner wall of the pipe, on which there is also no more loose material, so that a reliable disinfection can be assured. Furthermore, the wiper lip seals the tube (at least virtually) airtightly relative to the displacement tube, in any case better than the sliding rings do, so that a reliable transport of the relatively heavy tube can be ensured. The manifold sprays in the direction of displacement in the rearward direction, in contrast to what is the case in the solution of the aforementioned document DE 102016215447 B3. As a result, the disinfectant remains in the tube until it evaporates, since there is no slip ring that could wipe the agent off after its application, and the duration of its action is significantly longer, which enhances its effectiveness.

It is particularly preferred if the two solutions are combined in a single pneumatic dispatch tube, i.e. the tube in question has both UVC light sources and a nozzle for spraying a disinfectant.

Preferably, at least the sliding ring located next to the coarse brush has bristles made of synthetic fibers. This allows a thorough fine cleaning of the inner wall of the tube, with the removed material being captured by the synthetic fibers and discharged thereby. Furthermore, the sliding ring serves, of course, to guide the sleeve in a sliding manner through the tube.

It is interesting if the synthetic fibers and/or the large brush consist or consist of an antimicrobial material. In this way, the risk is limited that material removed from a tube, which was caught by the coarse brush or by the sliding ring, would cause contamination of another tube during further transport.

It is further preferred that the UVC light sources are provided in a recess of one or both of the box heads or in the immediate vicinity thereof. This serves for the mechanical protection of the UVC light sources. Often pneumatic dispatch stations have a belt drive which could damage the UVC light sources. This danger does not exist when the latter are arranged in a recess of the box head. The same applies if the UVC light sources are provided immediately after the tubular head, since the tubular head has a larger diameter than the tubular tube provided between the tubular heads, so that in that case too the UVC light sources are recessed, so to speak.

It is interesting if the UVC light sources are formed by flexible strips with LEDs arranged thereon, wherein these strips are arranged in the circumferential direction around the pneumatic post tube. Such strips can easily be arranged in recesses of the box heads or immediately in the vicinity of the box heads around the box tube.

Preferably, the storage reservoir is a pouch or a bag. The volume of a pouch or bag decreases as fluid is removed from it, as is known with infusion bags, so that the pouch or bag is always filled.

There is therefore no danger that the pump will suck in air when the position of the sleeve is changed, for instance when the direction of the tube is changed from horizontal to vertical as a result of a bend.

Ultimately, it is also interesting if two concentrically arranged tubes are provided between the tube heads, namely a tube tube and a closing tube, wherein these two tubes both have an opening and are rotatable relative to each other around the longitudinal axis of the tube tube, so that in a well-defined turning position the two openings are located one above the other, so that the interior of the tube tube is accessible, while in another rotational position the opening of the tube tube is covered by the closing tube. The duct according to the invention must have at least one energy source (a battery) and a corresponding electronic circuit, whereby these are components that must be easily accessible from the outside, and may not only be accessible from one end side or from both ends. sides of the tube. The proposed solution ensures this in a simple manner.

The present invention is explained in more detail by means of the accompanying drawing. The single figure 1 shows a cross-sectional view of a pneumatic post tube according to the invention in a transport tube.

Provided in a transport tube 1 is a pneumatic post tube whose supporting components are, as usual, two tube heads 21, 22 which are connected to each other by a tube tube 9. This pneumatic post tube is designed to be moved in the direction of arrow 2. The arrow 2 therefore indicates the direction of displacement. The terms “front” and “back”

In the following, therefore, always refer to this direction of displacement. The tubular head 21, which is located at the front in the direction of displacement, has a coarse brush 3 at the front, behind which a wiper lip 4 is provided.

When the pneumatic post tube moves through the transport tube 1, contaminants are removed from the inside of the transport tube by means of the coarse brush 3, and they are carried along by the wiper lip 4 . The wipe-off lip is formed from a flexible plastic material, for example from an elastomer.

Provided behind the wiper lip 4 is a sliding ring 5 which is designed in the form of fine flexible hairs and thus acts as a fine brush. This fine brush provides a fine, more thorough mechanical cleaning of the inside of the transport tube 1. At the same time, the sliding ring 5 brings about an easy and smooth sliding movement of the pneumatic post tube in the transport tube 1. Dust is carried along by the fine brush. When the bristles are made of an antimicrobial material, the risk of contamination is reduced when passing from one transport tube to another. The same applies to the coarse brush 3, which can also be made of an antimicrobial material. A sliding ring 5' is provided on the rear tube head 22, which can be designed just like the sliding ring 5, without however precluding that it is designed in the usual way.

Immediately behind the front box head 21 there is a flexible strip with LEDs forming the UVC light sources 8 in a recess. In a recess of the rear box head 22 there is a further flexible strip with LEDs which form the further UVC light sources 8 . The arrangement on or near the tube heads 21, 22 offers the advantage that the UVC light sources 8, 8 can be located near the transport tube 1, without the risk that they could collide with the latter in any bends of the transport tube. , as this would be the case with an arrangement in the middle of the pneumatic post tube. The arrangement in floors provides mechanical protection. The recesses should be relatively shallow so that the UVC light sources 8, 8 are not too far away from the transport tube 1.

Since UVC radiation is known to be hazardous to health (this radiation can in particular lead to conjunctivitis), a light sensor 6 is provided which — as soon as it detects light — switches off the UVC light sources. Only when the sensor detects no light, which is the case in the transport tube 1, the UVC light sources can transmit radiation.

In the pneumatic post tube there is furthermore a storage reservoir 14 in which a disinfectant is present. This is a standing pouch with a drain (spout bag). By using a flexible pouch, there is no negative pressure when pumping out the disinfectant, ensuring that the liquid can be completely pumped out in any position because the air pressure compresses the pouch in each of these positions. A rigid container would require an opening through which pressure compensation could be performed, but through which — should the opening be lowered during movement — the disinfectant could exit.

A pump 13 draws in the disinfectant from the storage reservoir 14 via a suction line 16 and pumps it via a spray line 17 to a manifold 18 which is arranged centrally in the rear tube head 22 . The manifold 18 may be an axial hollow-cone manifold with a fine atomization and a spray angle of 80°.

A mist 19 is hereby produced behind the pneumatic post tube, a mist with which the transport tube 1 is moistened from the inside.

The energy is supplied by means of a battery pack 11 which is connected to a circuit board 12. This circuit board 12 contains the electronic circuit for supplying all components with voltage, in particular the UVC light sources 8, 8' and the pump 13. It also contains the logic circuits for controlling these components, in particular in function of the signal from the light sensor

6. It is useful to always switch off the pump 13 when light is detected by the light sensor 6, since this means that the pneumatic dispatch tube is located outside the transport tube 1 at such moments. A radio module (eg Bluetooth) can also be provided, so that the functions of the pneumatic dispatch tube can be switched on and off externally.

Provided in each tube head 21, 22 is an RFID transponder 7 which identifies the pneumatic tube tube in an unambiguous manner by means of a tube ID, and in which also the transmitting and receiving station as well as the direction of movement can be stored.

The sleeve tube 9 is made of transparent and antimicrobial material, and has an opening 15. It is concentrically surrounded by a closure tube 10 which has an opening of the same area. The closing tube 10 also consists of a transparent and antimicrobial material, so that on the one hand the interior of the pneumatic post tube is visible from the outside, and so that on the other hand germs cannot remain attached to it for a long time. The closing tube 10 is rotatable relative to the tube tube 9 about the longitudinal axis of the pneumatic post tube. When the openings 15 in the tube tube 9 and in the closing tube 10 are located one above the other, this means that the interior of the pneumatic tube tube is accessible. In this state, one can top up disinfectant in the storage reservoir 14, charge the battery pack 11, or carry out other maintenance work. When the two tubes are rotated relative to each other until the closing tube completely covers the opening 15 in the tube tube 9, the pneumatic post tube is closed and can be used correctly.

Claims (10)

Conclusions Pneumatic tube tube for disinfecting a pipeline system of a pneumatic tube system, wherein the tube has a tube head (21, 22) each with a sliding ring (5, 5') at its two ends, wherein between the sliding rings (5, 5' ) UVC light sources (8, 8”) are provided, characterized in that a coarse brush (3) is provided on a tube head (21), in addition to the sliding ring (5), which is turned away from the other tube head (22). side of the sliding ring (5), and in that a wiper lip (4) is provided between the coarse brush (3) and the sliding ring (5). Pneumatic tube tube for disinfecting a pipeline system of a pneumatic tube system, wherein the tube has a tube head (21, 22) each with a sliding ring (5, 5) at its two ends, wherein a tube head (22) has a manifold ( 18) is provided for spraying a disinfectant, a pump (13) for pumping the disinfectant from a storage container (14) to the manifold (18), characterized in that on the opposite to the manifold (18) is provided located tubular head (21), in addition to the sliding ring (5), a coarse brush (3) is provided, which is located on the side of the sliding ring (5) remote from the tubular head (22) with the manifold (18), and in that a wiper lip (4) is provided between the coarse brush (3) and the sliding ring (5). Pneumatic tube as claimed in claim 1 and claim 2. Pneumatic tube according to one of Claims 1 to 3, characterized in that at least the sliding ring (5) located next to the coarse brush (3) has bristles made of synthetic fibers. Pneumatic tube according to claim 4, characterized in that the synthetic fibers consist of an antimicrobial material. Pneumatic tube according to one of Claims 1 to 5, characterized in that the coarse brush (3) consists of an antimicrobial material. Pneumatic tube according to Claim 1 or 2, and optionally 4 to 5, characterized in that the UVC light sources (8, 8') are located in a recess of a tube head or of both tube heads (21, 22) or in the immediate vicinity thereof to be provided. Pneumatic tube according to Claim 1 or 3, and optionally 4 to 7, characterized in that the UVC light sources (8, 8) are formed by flexible strips with LEDs arranged thereon, these strips being arranged in the circumferential direction around the pneumatic tube tube. Pneumatic tube according to Claim 1 or 2, and optionally 4 to 7, characterized in that the storage container (14) is a pouch. A tube post tube according to any one of claims 1 to 8, characterized in that two concentrically arranged tubes are provided between the tube heads (21, 22), namely a tube tube (9) and a closing tube (10), these tubes both having an opening ( 15), and are rotatable relative to each other about the longitudinal axis of the tubular tube, such that in a turning position the two openings (15) are located one above the other and that the interior of the tubular tube is thereby accessible, while in another turning position the opening (15) of the tubular pipe (9) is covered by the closing pipe (10).