JP6843423B2 - Nozzle device for oral cleaning device - Google Patents

Description

The present invention relates to a nozzle device for an oral cleaning device suitable for use in dentistry.

In dental practice, various oral cleaning devices for cleaning the inside of the periodontal pocket have been developed for the prevention of periodontal disease and peri-implantitis.
Patent Document 1 discloses a dental syringe having a nozzle provided with a water ejection hole at a central position and a plurality of air ejection holes inclined in the water ejection direction around the water ejection hole.
According to this dental syringe, it is assumed that the atomizing action is performed well and the straightness in the ejection direction is maintained.

Kimiaki 50-42228

In Patent Document 1, since a nozzle having a plurality of air ejection holes inclined in the water ejection direction is used around the water ejection holes, air is obliquely ejected from the plurality of air ejection holes, and the air is ejected. And water are strongly mixed, so that the atomization of water is good.
However, although it is assumed that the straightness of the atomized water is maintained, since the air is ejected diagonally from the plurality of air ejection holes, after the air from each air ejection hole once intersects at the tip of the nozzle, Since it spreads forward, there is a problem that a satisfactory linearity cannot be obtained.

The present invention has been made to solve the above problems, and an object of the present invention is to provide all nozzle devices for an oral cleaning device capable of obtaining good straightness of ejected liquid.

In order to achieve the above object, the present invention includes the following configurations.
That is, the nozzle device for an oral cleaning device according to the present invention has a grip portion and a nozzle provided in the grip portion, and is the nozzle device for oral cleaning that ejects a gas-liquid mixed fluid from the nozzle. The grip portion includes a liquid outlet for feeding a liquid into a liquid delivery path in the nozzle and an air outlet for sending compressed air to the air delivery path in the nozzle. A distance of 0.8 to 1.5 mm from one liquid ejection hole leading to the liquid ejection path provided and the liquid ejection hole, and a constant interval in the circumferential direction around the liquid ejection hole. In parallel with the liquid ejection holes, 3 to 8 holes having a hole diameter of 0.3 to 0.7 mm are provided, and the compressed air ejection holes provided in the nozzle and leading to the air delivery path are provided, and the liquid and the liquid are provided. It is characterized in that the compressed air becomes a gas-liquid mixed fluid ejected from the nozzle, is ejected linearly at a distance of 5 to 8 mm from the tip of the nozzle, and then spreads at a required diffusion angle. ..

A Coanda effect is generated between the compressed air ejection hole and each fluid ejected from the liquid ejection hole, and the compressed air clings to the liquid, so that straightness at a distance of 5 to 8 mm from the tip of the nozzle can be ensured. ..
Wherein it is preferable that the diffusion angle is 7 to 13 °.

It is preferable to use resin.
The liquid supplied to the liquid ejection hole is water.

According to the present invention, after liquid and compressed air are ejected from a nozzle, they become a gas-liquid mixed fluid and are ejected linearly at a distance of 5 to 8 mm from the tip of the nozzle, and then an oral cavity that spreads at a required diffusion angle can be obtained. Nozzle devices for cleaning devices can be provided. In this way, the gas-liquid mixed fluid (mist jet) can be ejected linearly at a distance of 5 mm to 8 mm, so that the optimum pressure range can be maintained without being aware of ensuring a constant distance between the affected area and the nozzle. It is easy, the distance between the affected part and the nozzle can be increased to improve the visibility, and stable cleaning can be performed while the cleaning effect is high. That is, it is possible to provide a nozzle device for an oral cavity cleaning device that enables spot cleaning even if the distance between the affected area and the nozzle is increased, the cleaning solution can be sprayed without waste, and the cleaning solution can be efficiently reached at the affected area.

It is a perspective view of the oral cavity cleaning apparatus. It is sectional drawing of the nozzle device. It is a partially enlarged sectional view of a nozzle. It is explanatory drawing of the nozzle tip part with 6 holes. It is explanatory drawing of the nozzle tip part with 8 holes. It is explanatory drawing of the nozzle which the tip part is facing up. It is explanatory drawing of the nozzle which the tip part is facing down. It is explanatory drawing which shows the diffusion angle. It is explanatory drawing which shows the spray waveform of the sample 1 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 2 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 3 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 4 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 5 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 6 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 7 of a nozzle. It is explanatory drawing which shows the spray waveform of the sample 8 of a nozzle.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a perspective view showing an overall outline of the oral cavity cleaning device 10, and FIG. 2 is a cross-sectional view of the nozzle device 12.
In FIG. 1, reference numeral 14 denotes a device main body.
Reference numeral 16 denotes a liquid container, which contains a liquid (water, a chemical solution) ejected from the nozzle device 12. The liquid container 16 is detachably attached to the apparatus main body 14 with the delivery port (not shown) facing downward.

The liquid contained in the liquid container 16 is sent to the nozzle device 12 by the liquid delivery mechanism. The liquid delivery mechanism feeds the liquid to the nozzle device 12 by a known tube pump 18. The tube pump 18 is driven by a motor (not shown). The rotation speed of the motor can be switched in three stages by the changeover switch 20, whereby the amount of liquid sent to the nozzle device 12 can be switched in three stages. The pump is not limited to the tube pump, and it goes without saying that other appropriate pumps can be used.

Further, a compressor (not shown) is connected to the connection port 22 by a hose to the device main body 14. The compressed air from the compressor is sent to the nozzle device 12 via the air delivery path in the device main body 14.
A regulator is incorporated in the air delivery path, and the air pressure sent to the nozzle device 12 can be adjusted by the regulator adjustment knob 24. Further, an electromagnetic valve (not shown) is incorporated in the air delivery path, and by controlling the on / off of the solenoid valve, the air delivery to the nozzle device 12 can be turned on / off.
Reference numeral 26 denotes a connection port to a commercial power source, and 28 is a power switch to the entire device main body 14.

FIG. 2 is a cross-sectional view of the nozzle device 12, and FIG. 3 is a partially enlarged cross-sectional view of the nozzle 32.
The nozzle device 12 has a nozzle 32 attached to the tip of the grip portion 30.
A liquid delivery hose 33 and a compressed air delivery hose 34 from the apparatus main body 14 are introduced into the grip portion 30.
The liquid delivery hose 33 is connected to the liquid delivery port 36, and feeds the liquid from the liquid delivery port 36 into the liquid delivery path 38 provided at the center of the nozzle 32.
The compressed air delivery hose 34 sends compressed air from the air delivery port 37 to the air delivery path 39 provided around the liquid delivery path 38 of the nozzle 32.

A liquid delivery path 38 and an air delivery path 39 extend in a double pipe shape in the nozzle 32.
The liquid delivery path 38 is opened as a small-diameter liquid ejection hole 38a at the center of the tip of the nozzle 32.
Further, the air delivery path 39 is temporarily closed at the tip of the nozzle 32, and is opened as a plurality of small-diameter compressed air ejection holes 39a in the closed portion. In the example shown in FIG. 4, six compressed air ejection holes 39a are provided, and in the example shown in FIG. 5, eight compressed air ejection holes 39a are provided.

The liquid ejection hole 38a and the compressed air ejection hole 39a are each opened by a drill having an appropriate diameter.
As shown in FIG. 3, the liquid ejection hole 38a and the compressed air ejection hole 39a have a length of several mm and are formed so as to be parallel to each other.
Further, a plurality of compressed air ejection holes 39a are formed around one liquid ejection hole 38a at equal intervals.

The tip of the nozzle 32 is bent in an L shape so that the liquid can be easily ejected into the periodontal pocket.
Further, the nozzle 32 is rotatably provided in the shaft hole 40 of the grip portion 30 about the axis line, whereby the tip portion faces upward (FIG. 6) and the tip portion faces downward (FIG. 7). ), And the periodontal treatment of the upper and lower teeth can be easily performed.
Reference numerals 41, 42, and 43 are O-rings, so that liquidtightness and airtightness between the shaft hole 40 and the shaft portion of the nozzle 32 are ensured.
It is preferable to provide a nozzle pop-out prevention structure so that the nozzle 32 does not pop out from the shaft hole 40 due to hydraulic pressure or air pressure. The nozzle pop-out prevention structure is not particularly limited, but for example, a flange portion 46 is provided on the outer circumference of the nozzle cylinder, and the front surface side of the flange portion 46 is pressed by a cap 47 screwed to the tip of the grip portion 30. Can be done (Fig. 2).

The nozzle 32, the liquid outlet 36, and the air outlet 37 are preferably made of resin so as to have chemical resistance.
The nozzle 32 can be formed into a double pipe structure by a stereolithography method using a 3D printer, powder lamination, or the like.
In the liquid delivery path 38 and the air delivery path 39, the inner and outer walls of the pipe are connected by the connecting portion 44 at appropriate positions in the circumferential direction so that the strength can be maintained (FIG. 3).
In FIG. 2, reference numeral 45 denotes a button switch, which can be turned on and off to turn on and off the motor in the liquid delivery mechanism and to turn on and off the solenoid valve in the air delivery path. And the compressed air can be sent and stopped.

The present embodiment is characterized in that the gas-liquid mixture fluid ejected from the tip of the nozzle 32 is set so as to spread at a required diffusion angle after being ejected from the tip of the nozzle 32 in a substantially linear shape at a required distance.
The distance at which this gas-liquid mixture fluid is linearly ejected from the tip of the nozzle 32 is preferably in the range of 5 mm to 8 mm from the tip of the nozzle 32. By ensuring a linear ejection distance of 5 mm to 8 mm in this way, it is possible to satisfactorily eject the fluid into the periodontal pocket, and it is possible to easily remove plaque and clean the inside of the periodontal pocket.

In addition, since the gas-liquid mixed fluid (mist jet) can be ejected linearly by 5 mm to 8 mm, the ejection angle becomes narrower, the mist jet is less likely to be diffused, and the spray pressure is less attenuated, so that it is within the range of the mist jet. The variation in pressure distribution can be reduced. As a result, the optimum pressure range in which the cleaning effect can be exhibited is widened. As a result, it is easy to maintain the optimum pressure range without being conscious of securing a constant distance between the affected area and the nozzle, and the distance between the affected area and the nozzle can be increased to improve visibility, and the cleaning effect is high. You will be able to perform stable cleaning as it is. In other words, it can be said that stable cleaning is possible regardless of the skill level of the operator. Further, even if the distance between the affected part and the nozzle is increased, the cleaning can be spotted and the cleaning liquid can be sprayed without waste, so that the cleaning liquid can reach the affected part efficiently. A high cleaning effect with a lower pressure and a lower liquid volume can also be obtained, and the burden on the patient is reduced.

By the way, the straightness (distance traveling straight) of the gas-liquid mixed fluid ejected from the tip of the nozzle 32 is the number of holes of the compressed air ejection hole 39a, the hole diameter, and the distance from the center of the liquid ejection hole 38a of the compressed air ejection hole 39a. It turns out that it is relatively dependent on. Further, when the compressed air ejection hole 39a extends in parallel with the liquid ejection hole 38a, the straightness of the gas-liquid mixed fluid is improved. In this way, because both holes 38a and 39a extend in parallel, the compressed air is ejected from the liquid ejection hole 38a instead of the compressed air colliding with each other unnecessarily due to the Coanda effect or the viscosity of the fluid. It is thought that straightness is improved by clinging to.
The atomization effect will be reduced to some extent.

When the number of holes in the compressed air ejection hole 39a is increased or the hole diameter is increased, the pressure of the compressed air ejected from the compressed air ejection hole 39a is reduced by that amount when the original pressure of the compressed air is the same. It affects the straightness of the mixed fluid. Further, if the distance of the compressed air ejection hole 39a from the center of the liquid ejection hole 38a (distance from the center to the center) is too large or too small, the Coanda effect is affected, and as a result, gas and liquid It affects the straightness of the mixed fluid.
It can be said that the straightness of the gas-liquid mixed fluid is affected by the magnitude of the original pressure of the compressed air, but the number and diameter of the compressed air ejection holes 39a and the distance from the center of the liquid ejection holes 38a are increased. Was found not to affect straightness.

Table 1 shows the data of various nozzles.
Table 1
In Table 1, the number of holes, the hole diameter, and the distance indicate the number of holes, the hole diameter, and the distance from the center of the liquid ejection hole of the compressed air ejection hole 39a. The diffusion angle is the angle shown in FIG. The diameter of the liquid ejection hole is 0.3 mm. “Straightness” indicates that the range in which the gas-liquid mixed fluid is ejected from the nozzle in a substantially straight line is 5 mm to 8 mm from the tip of the nozzle, and “None” indicates that it is less than 5 mm. The pressure (original pressure) of the compressed air is 0.3 MPa, and the flow rate of the liquid is 20 ml / min.

9 to 16 show spray waveforms of nozzle samples 1 to nozzle sample 8, respectively.
As shown in Table 1, FIG. 9 and FIG. 10, in the nozzle sample 1 and the nozzle sample 2, as the number of compressed air ejection holes increases, the diffusion angle of the gas-liquid mixed fluid tends to increase. Also, the straightness is low. Further, as shown in Table 1, FIG. 9, FIG. 15 and FIG. 16, in the nozzle sample 1 and the nozzle sample 7, if the pore diameter of the compressed air ejection hole becomes large, the diffusion angle of the gas-liquid mixed fluid also increases. It tends to be larger, and the straightness is also lower. Further, the smaller the number of holes, the smaller the diffusion angle of the gas-liquid mixed fluid and the better the linearity. Further, as can be seen from the nozzle sample 4 and the nozzle sample 8, when the distance from the nozzle center of the compressed air ejection hole is large to some extent, the diffusion angle of the gas-liquid mixed fluid is small and the straightness is good. You can see that.

The number of compressed air ejection holes is preferably about 3 to 8. In this case, the straightness of the gas-liquid mixed fluid (straightness from the nozzle end is 5 to 8 mm) can be obtained by selecting the pore diameter and the distance from the nozzle center.
Further, the diameter of the compressed air ejection hole is also preferably about 0.3 to 0.7 mm. In this case, by selecting the number of holes and the distance from the center of the nozzle, the straightness of the gas-liquid mixed fluid (the straightness from the nozzle end is 5 to 8 mm) can be obtained.
The distance from the center of the nozzle of the compressed air ejection hole should be about 0.8 to 1.5 mm. In this case, by selecting the pore diameter and the number of pores, the straightness of the gas-liquid mixed fluid (straightness from the nozzle end is 5 to 8 mm) can be obtained.
In these cases, the diffusion angle of the gas-liquid mixed fluid is approximately 7 to 13 °.
By ensuring straightness in this way, it was found that mild plaque can be easily removed only with a gas-liquid mixed fluid of water and air. In other words, it becomes easy to use because it is not necessary to use a chemical solution.

10 Oral cleaning device, 12 nozzle device, 14 device body, 16 liquid container, 18 tube pump, 20 changeover switch, 22 connection port, 24 adjustment knob, 26 connection port to commercial power supply, 28 power switch, 30 grip, 32 Nozzle, 33 Liquid delivery hose, 34 Compressed air delivery hose, 36 Liquid delivery port, 37 Air delivery port, 38 Liquid delivery path, 38a Liquid ejection hole, 39 Air delivery path, 39a Compressed air ejection hole, 40 shaft hole, 41 O Ring, 42 O-ring, 43 O-ring, 44 connecting part, 45 button switch, 46 flange part, 47 cap

Claims (5)

In a nozzle device for oral cleaning, which has a grip portion and a nozzle provided in the grip portion, and ejects a gas-liquid mixed fluid from the grip portion.
The grip portion includes a liquid outlet for feeding liquid into a liquid delivery path in a nozzle and an air outlet for sending compressed air to an air delivery path in the nozzle.
The nozzle has a liquid ejection hole at the tip thereof, which is provided in the nozzle and leads to the liquid delivery path, at a distance of 0.8 to 1.5 mm from the liquid ejection hole, and the liquid ejection hole. Three to eight holes with a hole diameter of 0.3 to 0.7 mm are provided around the holes at regular intervals in the circumferential direction in parallel with the liquid ejection holes, and are provided in the air delivery path provided in the nozzle. Equipped with a compressed air ejection hole that allows communication
After the liquid and the compressed air are ejected from the nozzle, they become a gas-liquid mixed fluid and are ejected linearly at a distance of 5 to 8 mm from the tip of the nozzle, and then spread at a required diffusion angle. A featured nozzle device for cleaning the oral cavity. A Coanda effect is generated between the compressed air ejection hole and each fluid ejected from the liquid ejection hole, and the compressed air clings to the liquid, so that straightness at a distance of 5 to 8 mm from the tip of the nozzle can be ensured. The nozzle device for the oral cleaning device according to claim 1, wherein the nozzle device is characterized by. The nozzle device for an oral cleaning device according to claim 1 or 2, wherein the diffusion angle is 7 to 13 °. The nozzle device for an oral cavity cleaning device according to any one of claims 1 to 3, wherein the nozzle device is made of resin. The nozzle device for an oral cavity cleaning device according to any one of claims 1 to 4, wherein the liquid supplied to the liquid ejection hole is water.