FI20207192A1 - Suction of air and accompanying harmful substances near the mouth of a patient at the dentist - Google Patents

Abstract

The object of the invention is a nozzle (1), an apparatus and a method for sucking air and harmful substances with it near the mouth (13) of a dental patient (12) and a method for manufacturing the nozzle (1) of the dental suction equipment. The nozzle (1) comprises a tubular casing (2) arranged around the imagined central axis (L). At the first end of the sheath (3) is the suction end (4) of the nozzle intended for the patient's mouth (13), and at the other end of the sheath (5) is the discharge end (6) of the nozzle. In the suction end (4) of the nozzle, the edge of the suction end (7) of the jacket is formed as an oblique relation to the central axis (L) of the nozzle. The sheath (2) is also flattened at its suction end (3) so that the sheath is at its widest at the long edge (8) of the suction end of the sheath when viewed in the direction of the central axis (L).

Description

Suction of air and harmful substances with it near the dentist's patient's mouth

TECHNICAL FIELD OF THE INVENTION The object of the invention is the nozzle, equipment and method for sucking harmful substances without and with it as described in the preambles of the independent patent claims presented below, as well as a method for making the nozzle of the dentist's suction equipment.

STATE OF THE ART Procedures performed in a dentist's office produce, for example, splashes, such as droplets or particles of different sizes. Larger splashes and drops fall quickly downwards. Small droplets and particles spread into the air as aerosols. Droplets, particles and aerosols can contain oral pathogens such as viruses. Into the treatment facility — when pathogens spread, they pose a health risk to the staff and other patients entering the same facility. It is known to protect yourself from drops by using protective equipment such as respirators, safety glasses or visors. Aerosols spread more widely and may remain suspended in the space for up to a couple of hours. It is known to try to remove aerosols from the air by ventilating, improving mechanical ventilation or using air cleaning devices. The removal of air from the mouth of a dentist's patient is known, for example, from patent publications AT 10972 U1, WO 8910154 A1, US 5513632 A, US 5127411 A, N US 6464499 B1. However, these have several disadvantages, such as the fact that the air-removing device - 25 — is uncomfortably attached to the patient's mouth or lips, for example, the structure of the device prevents the dentist or nurse from working, or hinders the use of work tools E, the device prevents visibility into the patient's mouth or shadows the lighting. Efficient N suction equipment not only absorbs drops easily, but also protective drapes, the patient's clothes and long S hair. Often, the suction is directed so that it spreads or lifts aerosols upwards, O 30 — so that the particles that do not end up in the cleaner fly even further.

PURPOSE OF THE INVENTION The purpose of the present invention is to reduce or even eliminate the aforementioned problems occurring in the state of the art.

One of the purposes of the present invention is to create a solution with which air and with it, for example, harmful substances contained in droplets and aerosols, are removed from those near the dentist's patient's mouth effectively and without harming the patient, staff or procedures performed on the patient.

One purpose of the present invention is to create a solution that minimizes the exposure of the patient, the staff and the environment to harmful substances used in dental procedures or released from the patient's mouth or contained in the patient's breath or saliva.

One purpose of the present invention is to create a solution that limits the spread of an infectious disease from an infected patient at a dentist's office.

BRIEF DESCRIPTION OF THE INVENTION In order to realize the aforementioned purposes, the nozzle, equipment, method and other objects of the invention according to the invention are characterized by what is presented in the attached independent patent claims.

O R The application examples and advantages mentioned in this text apply, where applicable, to nozzles, equipment, methods according to the invention as well as to other objects of the invention, & although it is not always mentioned separately. j N A typical nozzle according to the invention is intended for sucking air and harmful S substances with it near the dentist's patient's mouth. The nozzle comprises a tubular sheath arranged around the imagined central axis O 30 and - a suction head of the nozzle aimed at the patient's mouth at the first end of the sheath;

— at the other end of the jacket, the discharge end of the nozzle.

At the suction end of the nozzle — the edge of the suction end of the jacket is formed obliquely with respect to the central axis of the nozzle.

In this way, the jacket extends further on its long edge of the suction head in the direction of the central axis than on its short edge of the suction head.

In addition, — the jacket is flattened in shape at the suction end so that the jacket is at its widest when viewed in the direction of the central axis at the long edge of the jacket's suction end.

The nozzle according to the invention can be used in the equipment according to the invention to suck air and harmful substances with it near the dentist's patient's mouth.

The equipment comprises an air suction device and a nozzle according to the invention connected to it, with which the movement of air produced by the suction device is controlled as desired.

The suction equipment can comprise, for example, a suction pipeline, a fan, an air filter, control devices, = a computer and the = suction equipment arranged to run in it — management software.

In a typical method according to the invention, air and harmful substances are sucked from near the dentist's patient's mouth.

Suctioning is performed with an apparatus that comprises an air suction apparatus and a nozzle according to the invention connected to it, — in which case the method comprises at least the following steps: — air is blown with the suction apparatus; — the movement of air produced by the suction equipment near the patient's mouth is controlled by the nozzle.

S The method also includes at least the following steps: N — air is directed into the nozzle both over the long edge of the jacket suction end farther from the suction equipment 7 25 and over the short edge of the jacket suction end closer to the suction equipment.

Farther from the suction equipment means farther from the outlet end of the nozzle in the air flow direction z.

Closer to the intake means air S is closer to the discharge end of the nozzle in the direction of flow; S — air is directed to the nozzle as a flow with a flattened cross-section.

N 30 Flattened flow is achieved with a nozzle flattened at least at the suction end.

In this case, the flow is at its widest when viewed in the direction of the central axis of the nozzle at the long edge of the suction end of the jacket. The nozzle of the dental suction equipment according to the invention can be manufactured, for example, as follows: — the first end of a straight plastic or metal tube is formed obliquely with respect to the central axis of the tube and the second end is at least mainly perpendicular; — flatten the first end of the pipe, which is cut at an angle, so that the widest point of the end of the flattened pipe is placed at the longest point of the pipe.

In one application, the nozzle is formed from a straight tube. In one application, before being flattened, the tube is shaped like a right circular cylinder, a truncated right circular cylinder, or a truncated right circular cone.

So now it is understood that it is easy and effective to suck air and harmful substances near the dentist's patient's mouth with a simple nozzle, the edge of the suction head is formed obliquely and flattened. The oblique shape means that the suction end of the nozzle has a long and a short edge, whereby the long edge extends further in the direction of the imaginary central axis of the nozzle than the short edge. The flattening is done so that the suction end of the nozzle is at its widest at the long edge. In this way, the nozzle of the design can be used to control the suction air flow in a simple and effective way. It is easy to make the flattened nozzle stay firmly on the patient's chest and in the same position in relation to the patient's mouth without special ES attachment of the nozzle to the patient. During the treatment, it is often necessary to take tools or aids N over the patient's chest. Thanks to the flattened shape, it is easy for the dentist or nurse to work over the nozzle, even if the nozzle is firmly placed on the patient's chest. Thanks to the slanted edge of the suction head of the nozzle, the nozzle can be brought very close to E the patient's chin without having to place the nozzle even partially under the patient's chin. N The nozzle placed close to the chin means more effective removal of air and impurities S. Thanks to the design of the nozzle, the risk of objects such as the patient's clothes or O 30 hair, protective clothing, protective cloths being absorbed into the nozzle is lower than when using state-of-the-art suction equipment in the same way next to the patient. The suction power can be considered higher than in a state-of-the-art nozzle. The higher suction power effectively absorbs not only air, but also aerosols and droplets and, with them, impurities. The nozzle effectively changes the direction of splashing of droplets and aerosols away from the patient and medical staff.

5 The fact that the edge of the suction end of the jacket is formed obliquely with respect to the central axis of the nozzle can mean many different forms of the edge of the suction end. For example, the entire edge can be in one plane, or part of the edge or the entire edge can be curved in different ways. In one application, the sheath is flattened in shape at the suction end so that the sheath is at its widest when viewed in the direction of the central axis, not only at the long edge of the suction head, but also at the short edge of the suction end of the sheath. This flattened shape of the suction head enhances air suction exactly as desired.

In one application, the nozzle is used on the patient's chest so that it is as low as possible in height. For example, the nozzle can be set so that the long edge of the suction head or the short edge of the suction head is not facing the patient. In this case, the nozzle sucks in an air flow that is flattened in the vertical direction. In other words, the airflow is at its widest in the horizontal direction. In this way, air can be sucked in from as wide an area as possible. At the same time, the nozzle is less of a nuisance over the patient's chest — nursing work to be done.

In one application, the edge of the suction end of the jacket is formed at an angle with respect to the central axis o of the nozzle, for example at an angle of less than 60 degrees, less than 45 degrees, 30-60 degrees or less than 30 N degrees. In one application, an imaginary straight line passing through the long edge of the suction head and the short edge - 25 intersects the central axis of the nozzle at an angle of less than 60 degrees, less than & 45 degrees, 30-60 degrees, or less than 30 degrees. The slanted nozzle end can E be brought very close to the patient's mouth without the nozzle touching the patient. Compared to an N straight-cut pipe, an oblique cut creates a bigger opening than an S pipe of the same size. The slanted edge of the suction head of the nozzle therefore enables the sucking O 30 air flow to be directed efficiently and as desired.

In one application, the diameter of the sheath, viewed in the direction of the central axis of the nozzle, is greater than 100%, greater than 50%, greater than 25%, greater than 10%, 50-100%, 25-100% or 10-100% greater than the narrowest. The flattening of the nozzle jacket can be selected to suit each situation.

In one application, the central axis of the nozzle is straight all the way through the jacket. In one application, the center shaft runs the entire length of the nozzle inside the nozzle and does not intersect the nozzle jacket or its edges. The straight nozzle is easy to manufacture and easy and durable to use. A straight nozzle causes little pressure loss.

In one application, the sheath is symmetrical with respect to an imaginary surface parallel to the central axis of the nozzle passing through the long edge of the suction end of the sheath and the short edge. The symmetrical nozzle is easy to make and easy to use.

In one application, at the exit end of the nozzle, the section of the jacket perpendicular to the central axis of the nozzle is circular in shape. It is easy to arrange a connector to be connected to the suction pipeline on the circular end. It is easy to arrange a connector on the circular end, which allows the nozzle to be rotated in relation to the suction pipe.

In one application, the nozzle comprises means for controlling the shape of the suction end of the nozzle jacket, for example flattening, as desired. In this way, the suction airflow can be controlled better in different situations and for different patients, and the minimization of harmful substances spreading into the room air is enhanced.

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N = 25 In one application, recesses suitable for the shape of the patient's jaw are formed on the edge of the suction head of the diaper at the points of its long edge and short edge. The female nozzle E can be brought closer to the patient's head and especially to the mouth. In this way, the intake air flow N can be controlled better and the minimization of harmful substances S spreading into the room air is enhanced. S 30 In one application, the air suction equipment comprises a suction pipe system, on the basis of which the nozzle can be arranged in the desired position near the patient's mouth. In one application, the suction piping is self-supporting. In one application, there is a joint between the nozzle and the suction piping that allows the nozzle to be rotated relative to the suction piping. In this way, it is easy to place the piping and the nozzle in the desired position and they do not have to be supported on the patient.

In one application, there is a connector between the nozzle and the suction piping for releasably attaching the nozzle to the suction pipe of the suction equipment. Typically, the connection produced by the connector is at least mainly airtight. The connector can be on the discharge end of the nozzle, the suction pipe or both.

In one application, there is a coupling between the nozzle and the intake manifold that allows the nozzle to be rotated about its central axis relative to the intake manifold. By means of rotation, the nozzle can be placed in the desired position in relation to the patient. In one application, the suction airflow is controlled by rotating the nozzle around its central axis relative to the suction piping.

In one application, when using the invention, the nozzle and its imaginary central axis are placed at an angle relative to the horizontal plane so that the edge of the suction end of the diaper is placed near the patient's mouth and the outlet end of the nozzle is placed lower than the suction end, whereby air is sucked from near the patient's mouth downwards. In this way, air and harmful substances with it are sucked from near the patient's mouth downwards. It is the same direction in which gravity naturally pulls the droplets. In this way, the minimization of harmful substances spreading into the room air is enhanced.

S In one application, the nozzle according to the invention is made from a plastic or metal pipe as follows: a — the first end of the pipe is arranged perpendicular to the longitudinal axis E of the pipe; N — the other end of the pipe is arranged obliquely with respect to the longitudinal axis of the pipe, whereby a long edge and a short edge are formed at the other end of the S pipe; S 30 — one end of the pipe is flattened so that a flattened intake opening is formed. One or more of the following steps may be performed:

— shape a recess or recesses suitable for the jaw at one end of the tube; — one end of the pipe is flattened so that, viewed in the direction of the longitudinal axis, the diameter of the other end is largest at the long edge and the short edge; — a connector with which the nozzle can be attached to the suction pipe is arranged at the first end of the pipe. In one application, the nozzle is made of a malleable but relatively rigid material such as aluminum, steel or a suitable plastic. Examples of suitable plastics could be polyethylene (PE), high-density polyethylene (PE-HD), polypropylene (PP), polymethyl methacrylate (PMMA), i.e. acrylic. In one application, at least one end of the tube is heated before flattening to improve its malleability. The nozzle can be made in a different size as needed. The length of the nozzle or nozzle jacket in the direction of the central axis can be, for example, less than 100 cm, less than 80 cm, less than 60 cm, less than 40 cm, less than 20 cm, more than 20 cm, more than 40 cm, more than 60 cm, more than 80 cm, 10-100 cm , 30-100 cm, 50-100 cm, 10-60 cm, 10-40 cm, 30-50 cm, 30-70 cm, 50-80 cm. The maximum width of the nozzle or nozzle jacket, viewed in the direction of the central axis, can be, for example, more than 5 cm, more than 10 cm, more than 15 cm, more than 20 cm, more than 25 cm, less than 25 cm, less than 20 cm, less than 15 cm, less than 10 cm, 10-15 cm, 10-20 cm, 10-30 cm, 20-30 cm. The smallest width of the nozzle or nozzle jacket, viewed in the direction of the central axis, can be, for example, more than 5 cm, more than 10 cm, less than 25 cm, less than 20 cm, less than 15 cm, less than 10 cm, 5—15 cm, S 5-20 cm, 5-30 cm, 10-20 cm.

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S - 25 BRIEF DESCRIPTION OF THE DRAWINGS EO The invention is explained in more detail in the following by referring to the accompanying diagrammatic drawing E: where N Figure 1 shows a nozzle according to the invention; Figure 2 shows the placement of the nozzle according to the invention in the dental care unit; O 30 and

Figure 3 shows a nozzle according to the invention and a patient in a dental treatment unit, viewed from above.

DETAILED DESCRIPTION OF THE EXAMPLES OF THE DRAWINGS For clarity, the same reference numerals are used in the various drawings and embodiments of some corresponding parts. Figures 1-3 also show a nozzle 1 according to the invention for sucking air and harmful substances with it near the mouth 13 of the dentist's patient 12. The nozzle 1 — comprises a tubular jacket 2 arranged around the imagined central axis L. At the first end of the jacket 3 is the suction end 4 of the nozzle intended for the patient's mouth 13. At the other end of the jacket 5 is the outlet end 6 of the nozzle, from which the sucked air flow is led, for example, to the air filter. In the suction end of the nozzle 4, the edge 7 of the suction end of the jacket is formed obliquely with respect to the central axis L of the nozzle. In this way, the jacket 2 extends farther on its long edge 8 of the suction head in the direction of the central axis L than on its short edge 9 of the suction head. The suction end 3 of the jacket 2 is flattened. When viewed in the direction of the central axis L, the sheath is at its widest at the long edge 8 and short edge 9 of the suction head of the sheath. The jacket 2 of each nozzle 1 shown in Figures 1-3 is symmetrical with respect to the imaginary surface parallel to the central axis L of the nozzle passing through the long edge 8 and the short edge 9 of the suction head of the jacket. At the edge 7 of the suction head, at the points between its long edge 8 and short edge 9, recesses 11 for the patient's chin are formed. o The nozzle in Figure 1 comprises means 10 for controlling the flatness N of the suction end 3 of the nozzle jacket as desired. The nozzle 1 can also be made fixed in shape, like - 25 in Fig. 2 and 3. In this case, if desired, a nozzle of a different & shaped shape can be changed whenever necessary. j N The central axis L of each nozzle 1 is straight along the entire length of the jacket 2. The nozzle in figure 1 S was, before flattening, a truncated straight circular cone. The cross-section perpendicular to the central axis L of the nozzle O 30 — unflattened part increases all the way from the discharge end 4 towards the suction end 3. Figures 2 and 3 show the nozzles 1, which before flattening were cut straight circular cylinders. The cross-section perpendicular to the central axis L of the unflattened part of these nozzles remains the same when traveling from the discharge end 4 towards the suction end 3. In the discharge end 6 of all the nozzles of figures 1-3, the section of the jacket perpendicular to the central axis L of the nozzle is circular in shape.

The discharge end 6 of the nozzle has a connector for attaching the nozzle to the suction pipe of the suction equipment (not shown). In the suction piping and/or between the nozzle 1 and the suction piping, there may be one or more joints that allow the nozzle 1 to be rotated with respect to the suction piping. Between the nozzle 1 and the suction pipe there is a connector that allows the nozzle 1 to be rotated about its central axis L with respect to the suction pipe. In this way, the nozzle can be easily set in the desired position both in relation to the dental treatment unit 21 and the patient 12. In Fig. 2, the nozzle 1 according to the invention is shown in the dental care unit 21. The viewing angle in Fig. 2 is roughly what the dentist in his working position typically looks from. In Figure 2, there is no patient in the chair 22, but the picture shows how the nozzle is potentially in front when handling, for example, objects on the tray 23 or instruments 25 stored in the stand 24. The flattened shape of the nozzle 1 reduces the barrier effect of the nozzle 1 and makes the work of the dentist or nurse easier. In Figure 3, the nozzle 1 according to the invention is shown in the dental care unit 21, in which the patient 12 is in the chair 22. The view angle of Figure 3 is from above. The nozzle 1 is placed on the patient's chest in the picture from the bottom right towards the patient's mouth 13 and chin 14. The nozzle 1 o is turned around its central axis L so that the opening N defined by the edge 7 of the suction head opens slightly upwards. The recess 11 formed in the edge 7 fits the shape of the patient's jaw 14 - 25, and enables the nozzle 1 to be brought very close to the jaw 14, without touching it. The long edge 8 of the suction head is located on one side of the tip of the jaw, and the short edge E 9 is on the other side of the jaw. In this way, the nozzle 1 according to the invention enables N downward suction very close to the patient's mouth 13. The suction effectively draws splashes and aerosols flying from the patient S's mouth 13 into the nozzle 1. S 30

The invention is not intended to be limited to the presented examples, but the independent patent requirements determine the protection circle. The dependent claims present several advantageous applications of the invention.

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Claims (23)

PATENT CLAIMS 1. A nozzle (1) for sucking air and accompanying harmful substances near the mouth (13) of a dental patient (12), which nozzle (1) comprises a tubular sheath (2) arranged around an imaginary central axis (L) and — at the sheath first end (3) a suction end (4) on the nozzle intended for the patient's mouth (13); — at the other end of the casing (5) an outlet end (6) on the nozzle: characterized in that at the suction end of the nozzle (4) — the edge (7) on the suction end of the casing is shaped obliquely in relation to the central axis of the nozzle (L) so that the casing (2) extends further in the direction of the central axis (L) at its long edge (8) at the suction end than at its short edge (9) at the suction end, and — the casing (2) is flattened at its suction end (3) as seen in the central axis (L ) direction, the casing is widest at the long edge (8) on the suction end of the casing. 2. A nozzle according to claim 1, characterized in that — the casing (2) is flattened at its suction end (3) so that, seen in the direction of the central axis (L), the casing is widest at the short edge (9) on the suction end of the casing. 3. A nozzle according to claim 1 or 2, characterized in that the edge (7) on the suction end of the jacket is designed with an angle of less than 60 degrees, less than 45 degrees, 30-. 60 degrees or less than 30 degrees to the center axis of the nozzle (L). and N 4. A nozzle according to any of the preceding claims, characterized in that an imaginary line S 25 passing through the long edge (8) and the short edge (9) of the suction end N intersects the central axis (L) of the nozzle at an angle of less than 60 degrees, less than 45 degrees, E 30-60 degrees or less than 30 degrees. N > S 5. A nozzle according to any of the preceding claims, characterized in that the diameter of the jacket, seen in the direction of the central axis (L) of the nozzle, is at its widest over 100%, more than 50%, more than 25%, more than 10%, 50 -100%, 25-100% or 10-100% wider than narrowest. 6. A nozzle according to any of the preceding claims, characterized in that the central axis (L) of the nozzle is straight over the entire length of the jacket (2). 7. A nozzle according to any of the preceding claims, characterized in that the casing (2) is symmetrical with respect to an imaginary surface which is parallel to the central axis (L) of the nozzle and which passes through the long edge (8) and the short edge (9) ) on the suction end of the mantle. 8. A nozzle according to any of the preceding claims, characterized in that the cross-section of the casing perpendicular to the central axis (L) of the nozzle at the outlet end (6) of the nozzle has a circular shape. 9. A nozzle according to any of the preceding claims, characterized in that the outlet end (6) of the nozzle has a connection for attaching the nozzle to a suction tube of a suction device. 10. A nozzle according to one of the preceding claims, characterized in that it comprises means (10) for controlling the flattening of the suction end (3) on the casing nozzle to the desired level. N N 11. A nozzle according to any of the preceding claims, characterized in that recesses 5 25 (11) for the patient's chin are formed in the edge (7) of the suction end of the sheath between its N long edge (8) and short edge (9). E N 12. A device for suctioning air and accompanying harmful substances near the mouth (13) S of the dentist's patient (12), which device comprises an air suction device and a N 30 nozzle (1) connected thereto to control the air movement produced by the suction device , characterized in that the nozzle is according to any of preceding claims 1-11. 13. A device according to claim 12, characterized in that the air suction device comprises a suction tube system supported by which the nozzle (1) can be arranged near the patient's mouth (13) in the desired position. 14. A device according to claim 13, characterized in that the suction tube system is self-supporting. 15. A device according to claim 13 or 14, characterized in that there is a link between the nozzle and the suction pipe system which allows the nozzle (1) to be turned in relation to the suction pipe system. 16. A device according to any of the preceding claims 13-15, characterized in that there is a connection between the nozzle and the suction pipe system which enables the nozzle (1) to be rotated about its central axis (L) in relation to the suction pipe system. 17. A method for sucking air and accompanying harmful substances near the mouth (13) of a dentist's patient (12) with a device comprising an air suction device and a nozzle (1) connected thereto, the method comprising at least the following steps: — air is sucked with the suction device; — the air movement near the patient's mouth (13) produced by the suction device is controlled by the nozzle (1); characterized in that the nozzle (1) is according to one of the preceding claims 1-11 = whereby the method also comprises at least the following steps: N — air is directed to the nozzle (1) both over the long edge (8) on the suction end of the jacket S 25 farther from the suction device and over the short edge (9) on the mantle N sucked closer to the suction device; E — air is directed into the nozzle (1) as a flattened flow so that, seen in the direction of the S central axis (L) of the nozzle, the flow is widest at the long edge (8) of the suction end of the S casing. No. 30 18. A method according to claim 17, characterized in that the nozzle (1) is placed so that the edge (7) on the suction end of the mantle is placed close to the patient's mouth (13) and the outlet end (6) of the nozzle is placed lower than the suction end, whereby air is sucked downwards from near the patient's mouth mouth (13). 19. A method according to claim 17 or 18, characterized in that the air flow that is sucked is controlled by turning the nozzle (1) about its central axis (L) in relation to the suction pipe system. 20. A method according to one of the preceding claims 17-19, characterized in that the nozzle (1) is used on the patient's (12) chest so that the long edge (8) of the suction end or the short edge (9) of the suction end is not in contact with the patient. 21. A method according to any of the preceding claims 17-20, characterized in that the method uses a device according to any of the preceding claims 12-16. 22. A method of manufacturing a nozzle (1) for a dentist's suction device, wherein — a first end (3) of a straight plastic or metal tube is formed oblique to the central axis (L) of the tube and a second end (5) is formed perpendicularly ; — the first beveled end (3) of the pipe is flattened so that the widest point on the flattened end is formed at the longest point (8) of the pipe. S 23. A method according to claim 22, characterized in that recesses (11) suitable for the patient's chin (14) are formed at points between the longest point (8) and the shortest point (9) on the tube (2) beveled first end (3). N In Ao et al N oO ~ O QA O N