WO2022162952A1

WO2022162952A1 - Luminous vacuum tip

Info

Publication number: WO2022162952A1
Application number: PCT/JP2021/004855
Authority: WO
Inventors: 英世宇治
Original assignee: 英世宇治
Priority date: 2021-01-29
Filing date: 2021-01-29
Publication date: 2022-08-04
Also published as: WO2022163012A1; JPWO2022162952A1

Abstract

A drawback of a conventional vacuum tip is that when the vacuum tip is inserted into a surgical field and suction work is implemented, the vacuum tip body creates a shadow that darkens the surgical field. Furthermore, when a handpiece for cutting or a mirror is used, the shadow becomes even larger, resulting in a darker surgical field, and visibility of the surgical field cannot be sufficiently ensured with light from a shadowless lamp.　As a means for solving this problem, the present invention provides an illumination function on a vacuum tip, and also provides a mirror at the distal end of the vacuum tip.

Description

glowing vacuum tip

This invention relates to a vacuum tip for suction used in dentistry and medicine, which is characterized by having a suction function, a lighting function, and a mirror.

The oral cavity is one of the important organs connected to other organs and consists of soft and hard tissues. There are many diseases in the soft tissue, but tumors in the base of the tongue are particularly difficult to detect, and it was extremely difficult to observe the lesions on the tongue for a certain period of time with the tongue half turned inside out in the narrow oral cavity. . It was very difficult to detect lesions in the oral cavity at an early stage because the light did not reach the lesions in the operating light. Even in hard tissue, it was difficult to clearly identify the affected area, especially in the distal buccal side of the maxillary molar region and the root canal ostium of the mesial buccal root, because it was difficult for the surgical light to reach the root canal ostium. Conventional operating lights illuminate from a distance, and it was necessary to illuminate the affected area while avoiding the cutting handpiece or mirror held by the doctor or the vacuum at the hands of the assistant.
Conventionally, suction vacuum tips made of plastic or metal have been well known, which are called suction vacuum tips, in order to make it easier to see an affected area after suctioning. This type of suction vacuum tip is used in many fields of dentistry and medicine.
In dentistry, the narrow space of the oral cavity becomes dark when the handpiece for cutting and the vacuum tip for suction enter, so a shadowless light was necessary. With a conventional operating light, it was necessary to adjust the angle each time the angle of the patient's mouth changed even slightly. In addition, the strong light emitted by the vacuum chip in the oral cavity, which was not possible with conventional shadowless lights, makes it easy to recognize the cavities by projecting the cavities on the adjacent surfaces of the teeth and teeth in black, and emitting strong light from the back side of the teeth. The application makes it possible to see the cracks that occur in the tooth. Also, since the light is emitted near the affected area, the affected area can be easily seen.
In the medical field, doctors, nurses, and other staff stand around the operative field during surgery, etc., making the operative field dark and requiring a shadowless light. becomes easier to see.
SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a vacuum tip for suction that overcomes the drawbacks of the conventional shadowless lamp and vacuum tip for suction, and provides a vacuum tip that shines and has a suction function, an illumination function, and a mirror.

The problem we were trying to solve was the darkening of the operative field.

In the present invention, the vacuum tip and saliva ejector are provided with a suction function and a lighting function, and in addition, a mirror is installed at the tip of the vacuum tip.

The luminous vacuum tip and saliva ejector of the present invention can improve the efficiency of treatment by providing illumination as well as suction to improve the surgical field. A mirror is placed at the tip of the vacuum chip that shines at the same time, making it easy to use.

FIG. 1 shows a longitudinal section of the invention.
FIG. 2 shows a longitudinal section of the invention.
FIG. 3 shows a longitudinal section of the invention.
FIG. 4 shows a longitudinal section of the invention.
FIG. 5 shows a longitudinal section of the invention.
FIG. 6 shows a longitudinal section of the invention.
FIG. 7 shows a longitudinal section of the invention.
FIG. 8 shows a longitudinal section of the invention.
FIG. 9 shows a longitudinal section of the invention.
FIG. 10 shows a longitudinal section of the invention.
FIG. 11 shows a longitudinal section of the invention.
FIG. 12 shows a cross section of the invention.
FIG. 13 shows a cross section of the invention.
FIG. 14 shows a longitudinal section of the invention and FIG. 15 shows a transverse section of the invention.
FIG. 16 shows a cross section of the invention

For the purpose of improving the convenience of the vacuum chip, a lighting device and mirror are attached to the vacuum chip.

FIG. 1 shows a cross section of a glowing vacuum chip according to claim 1 and claim 2. It is shown in a schematic diagram for easy understanding. It is divided into a vacuum hose 16, a joint part 15 and a shining vacuum chip 14. - 特許庁Power supply 1 from the unit comes to the vacuum hose 16 to the switch and controller 2, and when it is on, the halogen bulb or LED light 4 lights up and passes through the optical fiber 5, which is separated in the figure for clarity, but in reality it is an optical fiber. The output contact surface 6 and the optical fiber input contact surface 7 are in contact. Light entering an optical fiber inlet 8 passes through an optical fiber 9 and is emitted toward an optical fiber outlet 10. - 特許庁

FIG. 2 shows a cross section of a glowing vacuum chip according to claim 3. FIG. It is shown in a schematic diagram for easy understanding. It is divided into a vacuum hose 16, a joint part 15 and a shining vacuum chip 14. - 特許庁Power supply 1 from the unit comes to the vacuum hose 16 to the switch and controller 2, and when it is on, the halogen bulb or LED light 4 lights up and passes through the optical fiber 5, which is separated in the figure for clarity, but in reality it is an optical fiber. The output contact surface 6 and the optical fiber input contact surface 7 are in contact. Light entering an optical fiber inlet 8 passes through an optical fiber 9 and is emitted toward an optical fiber outlet 10. - 特許庁
Furthermore, when the switch and the controller 2 are turned on, the inner halogen bulb or LED light 22 lights up, the inner optical fiber output 21 lights up, and the inner optical fiber output contact surface 21 and the vacuum chip input contact surface 23 come into contact with each other, and the vacuum 14 emits light. It is structured to convey to the whole.

FIG. 3 shows a cross-sectional view of a glowing vacuum chip according to the invention of claim 4. It is shown in a schematic diagram for easy understanding. It consists of a vacuum hose 16, a joint part 15 and a shining vacuum chip 36. - 特許庁When the power supply 1 is supplied to the vacuum hose 16 and the switch and controller 2 are on, the inner halogen bulb or

LED lights

31, 39 are lit, the inner

optical fiber outputs

32, 38 are lit, and the inner optical

fiber contact surfaces

33, 37 are connected. It is configured to transmit light and transmit the light to the entire

illuminated vacuum chip

35,36 in contact with the vacuum chip

input contact surfaces

34,40, which are separated in the drawing for clarity.

FIG. 4 is a view of a shining vacuum chip according to claim 11 with a mirror attached to the tip. A mirror is attached to the tip of the vacuum chip that shines, and when the mirror surface sucks up the fluid by negative pressure, it stands at a required angle with respect to the pipe direction and is attached obliquely to the pipe direction. The attachment is a mirror 64 fixed with female screws 60 and male screws 61 .

FIG. 5 shows a cross-sectional view of a glowing vacuum according to this invention. It is shown in a schematic diagram for easy understanding. The glowing vacuum tip is divided into a vacuum hose 92 and a glowing vacuum tip 90. - 特許庁The vacuum hose is composed of a power supply 81, a switch and controller 82, a halogen bulb 84 as a light source, etc. On the side of the vacuum chip that shines, an optical fiber 86 shines, a halogen bulb 84 as a light source on the hose side, and an optical fiber 86 that is in close contact. It is configured to be connected to a vacuum chip and emit light.

FIG. 6 shows a cross-sectional view of the glowing vacuum chip of claim 14. It is shown in a schematic diagram for easy understanding. The power supply 81 comes, then the switch and controller 82, then the power supply 83, and then the LED light 100 lights up. The optical fiber 102 attached to the glowing vacuum 88 is in close contact 101 with the LED light and the optical fiber, transmitting light to the optical fiber 102 and lighting the neon tube light 103 .

FIG. 7 shows a cross-sectional view of the glowing vacuum chip of claim 15. It is shown in a schematic diagram for easy understanding. After the power source 81 comes the switch and controller 82, then the power source 13, and then the halogen bulb 84. When the halogen bulb 84 is lit, the optical fiber 86 fixed to the glowing vacuum chip is fixed, but the halogen bulb and the optical fiber between the halogen bulb 84 and the optical fiber 86 are in close contact 85 . When the optical fiber 86 lights up, the neon tube light 103 lights up. In addition, a mirror is attached to the tip of the vacuum tip that shines.The mirror is attached to the tip of the vacuum tip that shines.When the mirror surface sucks up the fluid by negative pressure, it stands up at a required angle with respect to the pipe direction and is attached obliquely to the pipe direction. There is. The attachment is a mirror 64 fixed with female screws 60 and male screws 61 .

FIG. 8 shows a cross-sectional view of a glowing vacuum chip according to claim 15. FIG. 12 and 13 will also be briefly described. After the power supply 81 comes the switch and controller 82 and then the LED light 100 . When the LED light 100 is lit, the optical fiber 102 fixed to the glowing vacuum chip 90 is fixed, but the LED light between the LED light 100 and the optical fiber 102 is in close contact 101 . When the LED light 100 lights up, the neon tube light 103 lights up. In addition, a vacuum chip that has a mirror attached to the tip of the shining vacuum chip and the mirror shines. The mirror surface is attached to the tip of the tube and is attached obliquely to the tube direction so that it rises at a required angle with respect to the tube direction when the fluid is sucked up by the negative pressure. The attachment is a mirror 64 fixed with female screws 60 and male screws 61 .
The illuminated vacuum chip 90 consists of an optical fiber 102 that receives light and a neon tube light 103 that emits light. The optical fiber 102 is at least one optical fiber 102 and consists of a central core 140 and an outer cladding 141 . Only the central core 140 that enters the neon tube light 103 and emits light is turned toward the tip of the neon tube light 103 while spiraling inside the neon tube light 103 . Alternatively, it goes straight through the neon tube light 103 toward the tip of the neon tube light 103 .

FIG. 9 shows a cross-sectional view of a glowing vacuum chip according to claim 16. It is shown in a schematic diagram for easy understanding. After the battery 130 comes the power supply 81, then the switch and controller 82, then the power supply 83, and then the LED light 100. When the LED light 100 is turned on, the optical fiber 102 fixed to the glowing vacuum chip is fixed, but the LED light and the optical fiber 101 between the LED light 100 and the optical fiber 102 are in close contact. When the LED light 100 lights up, the neon tube light 103 lights up. In addition, a mirror is attached to the tip of the vacuum tip that shines, and the mirror is attached to the tip of the vacuum tip that shines. installed. The attachment is a mirror 64 fixed with female screws 60 and male screws 61 .

FIG. 10 shows a cross-sectional view of a glowing vacuum chip according to claim 17. It is shown in a schematic diagram for easy understanding. Power source 121 comes, then switch and controller 122, then power source 123, then LED light 124 lights up, which then travels through optical fiber 126 and neon tube light 103 lights up.

FIG. 11 illustrates the position of the cross section at AB according to the invention.
FIG. 12 is a cross section of A in FIG. Only the clearly lit vacuum tip is shown. An optical fiber 142 for receiving light from an LED light or a halogen bulb consists of a core 140 and a clad 141, and when it enters the neon tube light 144, only the core 140 is left. The core 140 emits light while spiraling in the substance 143, and in the cross section of B, the core 140 advances to the tip while spiraling in the substance 143 as it is. It should be noted that the structure is substantially translucent and emits light.

13 is a cross-sectional view of A of FIG. 11. FIG. It shows the position of the vacuum chip that shines in an easy-to-understand manner. An optical fiber 142 is provided on the light receiving surface for receiving the light of an LED light or a halogen bulb, a core 140 and a clad 141 are arranged, and the light enters a neon tube light 144, leaving only the core 140. When six optical fibers 142 are cores 140 and clads 141 in a light receiving part and enter a neon tube light 144, the six cores 140 run in the neon tube light 144 at equal intervals and go straight to a tip part 147 as they are.
FIG. 13B is the placement of core 140 at tip 147 . Incidentally, the material of the substance 143 is desirably translucent.

Fig. 14 shows a longitudinal section according to the present invention. Next to the power supply 123 comes the switch and controller 122, then the power supply 123, then the LED light 124 in the vacuum hose. When the LED light and the optical fiber are in close contact 101 and light is transmitted, the optical fiber 126 existing at the base of the vacuum tip consists of a core 140 and a clad 141, but when it exits the base 148, only the core 140 shown in FIG. It becomes a glowing vacuum chip that emits light toward 147.

Fig. 15 shows a cross section of the vacuum chip C that shines. It consists of a core 140 and a clad 141 until it exits the base portion 148, and in the cross section of D, when it exits the base portion 148, only the core 140 remains, and ideally, the cores 140 are arranged at equal intervals and advance to the tip while emitting light. .

Fig. 16 shows the cross section of C of the glowing vacuum chip. It consists of a core 140 and a clad 141 until it exits the base portion 148 , and in the cross section of D, when it exits the base portion 148 , only the core 140 is left and spirals in the substance 143 toward the tip portion 147 . It should be noted that the substance 143 is desirably translucent.

The glowing vacuum tip according to the present invention can work more efficiently when used in dentistry and medicine.

1. Power source 2. Switches and controllers3. power supply4. Halogen bulb or LED light5. Optical fiber output6. 7. Fiber optic output interface. 8. Fiber optic input interface. Optical fiber input9. optical fiber 10 . Optical fiber outlet 11 . work surface 12 . suction port 13 . non-working surface 14 . Luminous vacuum15. joint part 16 . Vacuum hose 20 . Inner fiber optic output contact surface 21 . inner fiber optic output 22 . Inner halogen bulb or inner LED light 23 . Vacuum tip input contact surface 31 . Inner halogen bulb or inner LED light 32 . inner fiber optic output 33 . inner fiber optic contact surface 34 . Vacuum tip input contact surface 35 . Luminous vacuum tip 36 . Luminous vacuum tip 37 . inner fiber optic contact surface 38 . inner fiber optic output 39 . Inner halogen bulb or inner LED light 40 . Vacuum tip input contact surface 60 . internal thread 61 . external thread 62 . holder 63 . mirror 64 . mirror surface 81 . power supply 82 . Switches and controllers 83 . power supply 84 . Halogen bulb 85 . The halogen bulb and the optical fiber are in close contact86. optical fiber 87 . Light 88. Luminous vacuum tip 89 . suction port 90 . Luminous vacuum tip 91 . joint rubber 92 . vacuum hose 93 . joint part 100 . LED lights 101 . The LED light and the optical fiber are in close contact 102 . optical fiber 103 . neon tube lights 121 . power supply 122 . Switches and controllers 123 . power supply 124 . LED lights 125 . The LED light and the optical fiber are in close contact 126 . optical fiber 127 . Saliva ejector 128 . light 129 . rubber 130 . battery 140 . Core 141 . cladding 142 . optical fiber 143 . Substantial 144. neon tube lights 145 . attachment 146 . Suction port 147 . tip 148 . base

Claims

When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs are lit, and the light of the halogen bulbs is emitted to the outside of the vacuum chip inserted into the joint. A glowing vacuum tip characterized by at least one receiving end of an optical fiber fixed to a part of the vacuum tip and light guided from the optical fiber directed to an opening and emitting light at an arbitrary location.
At least one or more LED lights are turned on when the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, and the light of the LED light is emitted to the outside of the vacuum chip inserted in the joint. A glowing vacuum tip characterized by at least one receiving end of an optical fiber fixed to a part of the vacuum tip and light guided from the optical fiber directed to an opening and emitting light at an arbitrary location.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs are lit, and the light of the halogen bulbs is emitted to the outside of the vacuum chip inserted into the joint. At least one or more ends of the receiving optical fiber are fixed to a part of the vacuum tip, the light guided from the optical fiber is directed to the opening and emits light at an arbitrary place, and at the same time the switch is turned on to remove the vacuum hose. A glowing vacuum chip characterized in that at least one or more halogen bulbs existing inside are lit and light from the end of the vacuum chip inserted into a joint spreads over the entire vacuum chip.
At least one or more LED lights are turned on when the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, and the light of the LED light is emitted to the outside of the vacuum chip inserted in the joint. At least one end of the receiving optical fiber is fixed to a part of the vacuum tip, the light guided from the optical fiber is directed to the opening and emits light at an arbitrary place, and at the same time the switch is turned on to remove the vacuum hose. A glowing vacuum chip characterized in that at least one or more LED lights existing inside are turned on, and light from the end of the vacuum chip inserted into a joint part spreads over the entire vacuum chip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs inside the vacuum hose will light up, and the vacuum chip inserted in the joint will turn on. A glowing vacuum tip characterized in that light from the end spreads over the entire vacuum tip.
When the power supply from the power supply reaches the end of the vacuum hose and the switch is turned on, at least one or more LED lights inside the vacuum hose will light up, and the vacuum chip inserted in the joint will turn on. A glowing vacuum tip characterized in that light from the end spreads over the entire vacuum tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs are lit, and the light of the halogen bulbs is emitted to the outside of the vacuum chip inserted into the joint. A glowing vacuum tip in which at least one or more receiving optical fiber ends are attached to a portion of the vacuum tip so that light directed from the optical fibers illuminates a neon tube light.
At least one or more LED lights are turned on when the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, and the light of the LED light is emitted to the outside of the vacuum chip inserted in the joint. A glowing vacuum tip in which at least one or more receiving optical fiber ends are attached to a portion of the vacuum tip so that light directed from the optical fibers illuminates a neon tube light.
When the power supply from the power supply unit reaches the end of the saliva ejector hose and the switch is turned on, at least one or more halogen bulbs light up, and the halogen bulbs are projected outside the saliva ejector inserted into the joint. At least one light receiving end of an optical fiber is attached to a portion of the vacuum tip and the light guided from the optical fiber illuminates a neon tube light.
When the power supply from the power supply unit reaches the end of the saliva ejector hose and the switch is turned on, at least one or more LED lights are lit, and the LED lights are displayed outside the saliva ejector inserted into the joint. At least one light receiving end of an optical fiber is attached to a portion of the vacuum tip and the light guided from the optical fiber illuminates a neon tube light.
Claim 1, characterized in that a mirror is attached to the tip of the vacuum chip that shines, and the mirror surface stands up at a required angle with respect to the pipe direction and is attached obliquely with respect to the pipe direction when the fluid is sucked up by negative pressure. , claim 2, claim 3, claim 4, claim 5, claim 6, claim 8, claim 9, claim 10, claim 12, claim 13, claim 14, claim 15, claim 18. The glowing vacuum chip according to claim 16 or 17.
The material is plastic, polypropylene, polyvinyl chloride, ABC resin, silicon rubber, SEBC material, TPE (thermoplastic elastomer). , Claim 7, Claim 9, Claim 10, Claim 11, Claim 13, Claim 14, Claim 15, Claim 16, and Claim 17.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs light up, and the optical fiber of the vacuum chip inserted into the joint is in close contact with the halogen bulb. , a glowing vacuum tip characterized by emitting a neon tube light.
At least one or more LED lights are turned on when the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, and the optical fiber of the vacuum chip inserted into the joint is in close contact with the LED light. , a glowing vacuum tip characterized by emitting a neon tube light.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more LED lights are lit, and the optical fiber of the vacuum chip inserted into the joint part is in close contact with the LED light. , The neon tube light is emitted, and the mirror surface attached to the tip of the vacuum tip rises at a required angle with respect to the pipe direction and is attached obliquely to the pipe direction when the fluid is sucked up by negative pressure. A glowing vacuum tip.
When the battery comes to the end of the vacuum hose and the switch is turned on, the LED light lights up, and the optical fiber of the vacuum chip inserted into the joint part adheres to the LED light, causing the neon tube light to emit light. A glowing bar characterized in that a mirror surface attached to the tip rises at a required angle with respect to the pipe direction and is attached obliquely with respect to the pipe direction when sucking up a fluid by negative pressure.
At least one or more LED lights are turned on when the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, and the optical fiber of the vacuum chip inserted into the joint is in close contact with the LED light. A glowing vacuum tip that features a neon tube light that lights up at the tip and brightly illuminates the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more LED lights are lit, and the optical fiber of the vacuum chip inserted into the joint part is in close contact with the LED light. , A glowing vacuum tip that consists of a core and a clad, and when it enters the neon tube light, it turns into a core and spirals toward the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more LED lights are lit, and the optical fiber of the vacuum chip inserted into the joint part is in close contact with the LED light. , A glowing vacuum chip characterized by comprising a core and a clad and forming a core when entering a neon tube light, with at least one or more cores extending linearly toward the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs light up, and the optical fiber of the vacuum chip inserted into the joint portion adheres to the halogen bulb. , A glowing vacuum tip that consists of a core and a clad, and when it enters the neon tube light, it turns into a core and spirals toward the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs light up, and the optical fiber of the vacuum chip inserted into the joint portion adheres to the halogen bulb. , A glowing vacuum chip characterized by comprising a core and a clad and forming a core when entering a neon tube light, with at least one or more cores extending linearly toward the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more LED lights are lit inside the vacuum hose, and the optical fiber of the vacuum chip inserted into the joint is turned on by the LED. A glowing vacuum tip that is in close contact with a light, is composed of a core and a clad at its base, becomes a core when it enters a working part, and has at least one or more cores extending linearly toward the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more LED lights are lit inside the vacuum hose, and the optical fiber of the vacuum chip inserted into the joint is turned on by the LED. A glowing vacuum tip which is closely attached to a light, and which consists of a core and a clad at the base, becomes a core at the time of entering the working part, and has at least one or more cores spiraling toward the tip direction.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs light up in the vacuum hose, and the optical fiber of the vacuum chip inserted into the joint unit is connected to the halogen bulb. A glowing vacuum chip characterized by being in close contact with a sphere, comprising a core and a clad and forming a core when it enters a working part, and at least one or more cores are directed linearly toward the tip.
When the power supply from the power supply unit reaches the end of the vacuum hose and the switch is turned on, at least one or more halogen bulbs light up in the vacuum hose, and the optical fiber of the vacuum chip inserted into the joint unit is connected to the halogen bulb. A glowing vacuum tip that adheres closely to the ball, consists of a core and a clad, and when it enters the working part, it turns into a core and spirals toward the tip.
Claim 2, Claim 4, Claim 6, Claim 8, Claim 10, Claim 14, Claim 15, Claim 16, Claim 17, characterized in that the transmission system of the optical fiber is multimode. 24. The vacuum tip of claim 18, claim 19, claim 21, claim 22 and claim 23.
Claim 2, Claim 4, Claim 6, Claim 8, Claim 10, Claim 14, Claim 15, Claim 16, Claim 17, characterized in that the transmission system of the optical fiber is a single mode. 24. The vacuum tip of claim 18, claim 19, claim 21, claim 22 and claim 23.
Claim 13, characterized in that a mirror is attached to the tip of the vacuum chip that shines, and the mirror surface stands up at a required angle with respect to the pipe direction and is attached obliquely with respect to the pipe direction when the fluid is sucked up by negative pressure. , Claim 14, Claim 15, Claim 16, Claim 17, Claim 18, Claim 19, Claim 20, Claim 21, Claim 22, Claim 23, Claim 24 and Claim 25 vacuum tip.
The material is plastic, polypropylene, polyvinyl chloride, ABC resin, silicon rubber, SEBC material, TPE (Thermoplastic Elastomer). , 19, 20, 21, 22, 23, 24 and 25. The vacuum tip of claim 25.
Claim 1, Claim 2, Claim 3, Claim 4, Claim 5, Claim 6, Claim 7, Claim 8, Claim 9, Claim 10, wherein the Kelvin number is 5500K. , claim 11, claim 12, claim 13, claim 14, claim 15, claim 16, claim 17, claim 18, claim 19, claim 20, claim 21, claim 22, claim 30. The glowing vacuum tip according to claim 23, claim 24, claim 25, claim 26, claim 27, claim 28 and claim 29.
Claim 1, claim 2, claim 3, claim 4, claim 5, claim 6, claim 7, characterized by having a controller capable of adjusting the luminous flux between 0.1 lumen and 640 lumen. Claim 8, Claim 9, Claim 10, Claim 11, Claim 12, Claim 13, Claim 14, Claim 15, Claim 16, Claim 17, Claim 18, Claim 19, Claim 20, 21, 22, 23, 24, 25, 26, 27, 28, 29 and 30. The glowing vacuum tip.