JP6542111B2 - Gas meter and light guide - Google Patents

Description

  The technology disclosed herein relates to gas meters and light guides.

  The gas meter disclosed in Patent Document 1 includes a light source that emits light when the gas supply is shut off, and a return button for returning the shut off gas supply. Moreover, the gas meter of patent document 1 is provided with the light guide which guide | induces the light of a light source around a return button. The light guide of Patent Document 1 includes a first light guide for guiding the light of the light source to the inside of the light guide, and a second light guide for guiding the light passing through the first light guide around the return button. ing. The first light guide includes an incident surface facing the light source and a first reflecting surface facing the opposite side to the incident surface. The first reflective surface is inclined with respect to the incident surface. In addition, the second light guide portion includes an emission surface facing the side opposite to the light incident surface of the first light guide portion, and a second reflection surface facing the light incident surface side. The exit surface and the second reflection surface are formed in parallel.

  According to such a configuration, the light emitted by the light source enters the inside of the light guide from the incident surface of the first light guide, is reflected by the inclined first reflection surface of the first light guide, and travels , And enters the second light guide from the first light guide. The light that has entered the second light guide portion is reflected by the second reflection surface of the second light guide portion, travels toward the exit surface, and exits from the exit surface.

JP, 2008-216033, A

  In the light guide of patent document 1, since the 1st reflective surface of a 1st light guide part inclines, it reflects by the 1st reflective surface which inclined the light which injected into the 1st light guide part, and the 2nd light guide It can be led inside the department. However, only by reflecting the light incident on the first light guide on the first reflection surface and causing the light to be incident on the second light guide, the light is moved to a position far from the first light guide inside the second light guide. I could not lead enough. That is, light could not be sufficiently guided to the back of the second light guide. Therefore, the area around the return button could not be bright enough. Since the gas meter is generally installed outdoors, when the area around the gas meter is dark at night, it becomes difficult for the user to know the position of the return button. Therefore, it is required to brighten the area around the return button. Thus, the present specification provides a technique that can brighten the entire circumference of the return button.

  The gas meter disclosed herein includes a light source that emits light when the gas supply is shut off, and a return button for restoring the shut off gas supply. The gas meter includes a light guide that guides the light of the light source around the return button. The light guide includes a first light guide that guides the light of the light source into the light guide, and a second light guide that guides the light passing through the first light guide around the return button. The first light guide includes an incident surface facing the light source side. The second light guide portion includes an emission surface facing the incident surface and a reflection surface facing the incident surface. The reflecting surface is inclined so as to move away from the exit surface and approach the entrance surface as it approaches the first light guide.

  According to such a configuration, the light emitted by the light source enters the first light guide from the incident surface, passes through the first light guide, and enters the second light guide. The light incident on the second light guide has components in various directions. For example, it has a component that travels inside the second light guide toward the exit surface and a component that travels toward the reflection surface. Light traveling toward the exit surface exits from the exit surface. In addition, the light traveling toward the reflecting surface is reflected by the reflecting surface to change the traveling direction, and further travels inside the second light guide. Since the light incident on the second light guide section travels in various directions, the light spreads over the entire second light guide section, and the light is guided around the return button all around. Moreover, according to said structure, as the reflective surface of a 2nd light guide part approaches a 1st light guide part, it is inclined so that it may go away from an output surface and it may approach an entrance surface. By this, the light quantity when the light which injected into the 1st light guide part from the entrance plane enters into the 2nd light guide part can be increased. Furthermore, the light incident on the second light guide portion is reflected by the inclined reflection surface and proceeds further to the inside of the second light guide portion, so a portion far from the first light guide portion inside the second light guide portion Can also guide light. Reflected light can be guided to the back of the second light guide by the inclination of the reflection surface of the second light guide. Thus, light can be guided through the entire second light guide. As a result, the entire periphery of the return button can be brightened.

  The light guide disclosed herein is used in a gas meter that includes a light source that emits light when the gas supply is shut off, and a return button for returning the shut off gas supply. The light guide includes a first light guide for guiding the light of the light source to the inside, and a second light guide for guiding the light passing through the first light guide around the return button. The first light guide includes an incident surface facing the light source side. The second light guide portion includes an emission surface facing the incident surface and a reflection surface facing the incident surface. The reflecting surface is inclined so as to move away from the exit surface and approach the entrance surface as it approaches the first light guide.

  According to such a configuration, as described above, the light can be guided through the entire second light guide, and the entire periphery of the return button can be brightened.

It is a front view of a gas meter concerning an example. It is an exploded perspective view of a gas meter concerning an example. It is an enlarged view of the principal part III of FIG. It is IV-IV sectional drawing of FIG. It is a perspective view of the main lighting body which concerns on an Example. It is a side view of the main lighting body concerning an example. It is a side view of the main lighting body which concerns on another Example.

  The main features of the embodiments described below are listed. The technical elements described below are technical elements independent of each other, and exert technical usefulness by themselves or various combinations.

  (Feature 1) It is preferable that the reflective surface of the second light guide be connected to the incident surface of the first light guide.

  According to such a configuration, it is possible to widen the portion where light is incident from the first light guiding portion to the second light guiding portion. By this, the light quantity when the light which injected into the 1st light guide part from the entrance plane enters into the 2nd light guide part can further be increased. As a result, the area around the return button can be further brightened.

  Hereinafter, embodiments will be described with reference to the drawings. As shown in FIGS. 1 and 2, the gas meter 1 according to the embodiment includes a main body 2 and a cover 3. The gas meter 1 is installed, for example, in a house or a factory. The gas meter 1 is a device that measures the amount of gas used in a house or a factory. The gas meter 1 is installed outdoors.

  The main body 2 is provided with an inflow pipe 25 and an outflow pipe 26. A flow passage (not shown) connecting the inflow pipe 25 and the outflow pipe 26 is formed in the inside of the main body 2. Gas flows in through the inflow pipe 25, flows through the flow path, and flows out of the outflow pipe 26. Moreover, the main body 2 is provided with the shut-off valve (illustration omitted) which can interrupt | block the flow path. The shutoff valve is provided between the inflow pipe 25 and the outflow pipe 26. When the shutoff valve is closed, the flow of gas is shut off. This shuts off the gas supply. For example, in the case of a gas leak, the shutoff valve is closed to shut off the gas supply. On the other hand, when the shutoff valve opens, gas flows.

  A counter 21 and a substrate 22 are disposed in the main body 2. The counter 21 includes a plurality of numeral cars 23 arranged side by side. The counter 21 displays the integrated value of the flow rate of gas by the plurality of numeral wheels 23. The amount of gas used can be grasped by the counter 21.

  A light source 31 and a switch 32 are disposed on the substrate 22. The light source 31 and the switch 32 are arranged side by side. The light source 31 and the switch 32 are disposed apart from each other.

  The light source 31 is, for example, one light emitting diode (LED). The light source 31 faces the front side of the gas meter 1. The light source 31 emits light toward the front side of the gas meter 1. The light source 31 emits light when the shutoff valve described above is closed and the gas supply is shut off. The light source 31 notifies by light that the gas supply is shut off. The light source 31 is supplied with power from a power supply 39. The power source 39 is, for example, one dry battery.

  The switch 32 is disposed next to the light source 31. The switch 32 faces the front side of the gas meter 1. When the switch 32 is pressed, a valve opening instruction is sent to the shutoff valve. This opens the shutoff valve. When the switch 32 is pressed while the shutoff valve is closed and the gas supply is shut off, the shutoff valve is opened, the shutoff is released, and the gas supply is restored.

  The cover 3 is disposed in front of the main body 2. The cover 3 is fixed to the main body 2. The cover 3 covers the counter 21 and the substrate 22 disposed in the main body 2. As shown in FIG. 3, a plurality of light guide openings 35 and a single button opening 34 are formed in the front of the cover 3. A plurality of light guide openings 35 are formed around the button opening 34. The plurality of light guide openings 35 surround the button opening 34. The button opening 34 is formed inside the plurality of light guide openings 35.

  As shown in FIG. 4, the main light guide 10, the sub light guide 70 and the return button 40 are fixed to the cover 3. The main light emitting body 10, the sub light guide 70, and the return button 40 are arranged in order from the main body 2 side toward the cover 3 side.

  The main light guide 10 is disposed in front of the light source 31. The main light guide 10 is disposed to face the light source 31. The main light guide 10 is light transmissive. The main light guide 10 is formed of a colorless and transparent material. A through hole 15 is formed in the main light guide 10. The return button 40 and the switch 32 are located inside the through hole 15. As shown in FIGS. 5 and 6, the main light guide 10 includes a first light guide 11 and a second light guide 12. The first light guide 11 and the second light guide 12 are integrally formed.

  As shown in FIG. 4, the first light guide 11 is located in front of the light source 31. The first light guide 11 faces the light source 31. The first light guide 11 is formed in a generally cylindrical shape. The first light guide 11 extends in the axial direction of the shaft 41 of the return button 40. The first light guide 11 extends along the pressing direction of the return button 40. The first light guide portion 11 includes an incident surface 16. The incident surface 16 faces the back side of the gas meter 1. The incident surface 16 faces the light source 31 side. The incident surface 16 is located in front of the light source 31. The incident surface 16 faces the light source 31. The light emitted by the light source 31 is incident on the first light guide 11 from the incident surface 16. The first light guide unit 11 guides the light of the light source 31 from the incident surface 16 to the inside of the main light 10.

  The second light guide 12 is located next to the first light guide 11. The second light guide 12 is generally formed in a cylindrical shape. The outer peripheral portion of the second light guide portion 12 and the outer peripheral portion of the first light guide portion 11 are coupled. The light having passed through the first light guide 11 is incident on the second light guide 12 from the coupling portion. The second light guide 12 extends in the axial direction of the shaft 41 of the return button 40. The second light guide 12 extends in the pushing direction of the return button 40. The second light guiding portion 12 surrounds the switch 32 and the return button 40 all around. The second light guide 12 guides the light that has passed through the first light guide 11 and is incident on the second light guide 12 around the return button 40.

  The second light guide unit 12 includes an emission surface 17 and a reflection surface 18. The exit surface 17 faces the front side of the gas meter 1. The emitting surface 17 faces the cover 3 side. The exit surface 17 faces the side opposite to the entrance surface 16 of the first light guide 11. The light having passed through the second light guide 12 is emitted from the emission surface 17 to the outside of the main light 10. The light is emitted toward the front side of the gas meter 1.

  The reflective surface 18 faces the back side of the gas meter 1. The reflecting surface 18 faces the incident surface 16 side of the first light guiding portion 11. The reflective surface 18 does not face the light source 31. The reflective surface 18 is connected to the incident surface 16. The reflecting surface 18 and the incident surface 16 are formed to be continuous. The reflective surface 18 is inclined with respect to the axial direction of the shaft portion 41 of the return button 40. The reflecting surface 18 is inclined with respect to the pressing direction of the return button 40. The reflecting surface 18 is inclined so as to move away from the emission surface 17 as it approaches the first light guide portion 11 and to approach the incident surface 16. The reflecting surface 18 is inclined so as to be directed to the back side of the gas meter 1 as it approaches the first light guiding portion 11.

  The sub light guide 70 is disposed in front of the main light 10. The sub light guide 70 is disposed to face the main light 10. The sub light guide 70 is light transmissive. The sub light guide 70 is formed of a colorless and transparent material. The sub light guide 70 guides the light emitted from the main light 10 to the front side of the gas meter 1. A through hole 75 is formed in the sub light guide 70. The return button 40 is inserted into the through hole 75. The sub light guide 70 surrounds the entire circumference of the return button 40.

  The sub light guide 70 includes an entrance surface 71 and an exit surface 72. The incident surface 71 faces the back side of the gas meter 1. The incident surface 71 faces the main light guide 10 side. The incident surface 71 is located in front of the main light 10. The incident surface 71 faces the exit surface 17 of the second light guide 12 of the main light 10. Light emitted from the emission surface 17 of the main light guide 10 enters the sub light guide 70 from the incident surface 71. The exit surface 72 of the sub light guide 70 faces the front side of the gas meter 1. The exit surface 72 faces the side opposite to the entrance surface 71 of the sub light guide 70. The light having passed through the inside of the sub light guide 70 is emitted from the emission surface 72 to the outside. The light is emitted toward the front side of the gas meter 1. As shown in FIG. 3, the emission surface 72 of the sub light guide 70 is exposed from the light guide opening 35 formed in the cover 3. Light is emitted through the light guide opening 35.

  The return button 40 is disposed to face the switch 32. The return button 40 does not transmit light. The return button 40 is formed of, for example, a black resin. The return button 40 includes a shaft 41 and a cover 42. The shaft 41 and the cover 42 are integrally formed. The shaft portion 41 extends in the front-rear direction of the gas meter 1. The shaft 41 is disposed to face the switch 32. The cover 42 covers the shaft 41. As shown in FIG. 3, the cover portion 42 is exposed from the button opening 34 formed in the cover 3. The user can press the return button 40 through the button opening 34. The return button 40 is configured to restore the shutoff gas supply. When the return button 40 is pushed toward the switch 32, the shaft 41 of the return button 40 presses the switch 32. When the switch 32 is pressed, the shutoff valve is opened, the shutoff is released, and the gas supply is restored.

  In the gas meter 1 having the above configuration, the light source 31 emits light when the shutoff valve is closed and the gas supply is shut off. The light emitted from the light source 31 is incident on the first light guiding portion 11 from the incident surface 16 of the first light guiding portion 11 of the main light body 10, passes through the first light guiding portion 11, and is transmitted to the second light guiding portion 12. Incident to The light incident on the second light guide 12 has components in various directions. For example, as indicated by an arrow 91 in FIG. 6, there is a component that travels the inside of the second light guide 12 toward the emission surface 17 or a component that travels toward the reflective surface 18 as shown by an arrow 92. Among the light traveling in various directions, the light traveling toward the emission surface 17 is emitted from the emission surface 17 as it is. In addition, the light traveling toward the reflecting surface 18 is reflected by the reflecting surface 18 to change the traveling direction, and further travels to the back of the second light guide portion 12. Light traveling in various directions travels to the entire second light guide 12, and the entire second light guide 12 becomes bright. Thereby, light is guided around the return button 40 all around. In the main light guide 10 described above, the reflecting surface 18 of the second light guiding portion 12 is inclined so as to be farther from the light emitting surface 17 and closer to the light incident surface 16 as it approaches the first light guiding portion 11. By this, the area | region where light injects into the 2nd light guide part 12 from the 1st light guide part 11 can be expanded, and the light quantity when light injects into the 2nd light guide part can be increased. Furthermore, since the light incident on the second light guide portion 12 is reflected by the inclined reflection surface 18 and proceeds further to the inside of the second light guide portion 12, the first light guide inside the second light guide portion 12 The light can also be guided to a part far from the part 11. The reflected light can be guided deep into the second light guide 12 by the inclination of the reflection surface 18 of the second light guide 12. Thus, light can be guided throughout the second light guide 12. As a result, it is possible to brighten the entire circumference of the return button 40. The user can easily grasp the position of the return button 40.

  Further, in the main light guide 10 described above, the reflection surface 18 of the second light guide 12 is connected to the light incident surface 16 of the first light guide 11, and both are continuous, so from the first light guide The area where light enters the second light guide can be made wider. As a result, the amount of light when light is incident from the first light guiding portion to the second light guiding portion can be further increased. As a result, the area around the return button 40 can be further brightened. Moreover, since the above-mentioned gas meter 1 is installed outdoors, the surroundings of the gas meter 1 become dark at night. Then, it becomes difficult for the user to grasp the position of the return button 40. Therefore, in the gas meter 1 installed outdoors, the above-mentioned technology capable of brightening the area around the return button 40 is particularly effective. In addition, the gas meter 1 is generally used continuously for a long period (for example, 10 years), and the power supply 39 (dry battery) is hardly exchanged during the use period. It is preferable to suppress the consumption. For that purpose, it is preferable to suppress the light quantity of the light source 31, but when the light quantity of the light source 31 is suppressed, the area around the return button 40 becomes dark in the prior art. However, according to the above-described technology, as the reflection surface 18 of the second light guide 12 approaches the first light guide 11 and is further away from the emission surface 17 and inclined so as to approach the incident surface 16, the light amount is increased. Even if the light source 31 has a small amount of light, the area around the return button 40 can be sufficiently bright.

  In the gas meter 1 described above, when the user presses the return button 40 after the gas supply is shut off, the switch 32 is pressed by the return button 40 and the valve opening instruction is sent to the shutoff valve. Then, the shutoff valve is opened, the shutoff is released, and the gas supply is restored.

  As mentioned above, although one Example was described, a specific aspect is not limited to the said Example. In the following description, the same components as those in the above description will be assigned the same reference numerals and descriptions thereof will be omitted.

  In the above embodiment, the reflecting surface 18 of the second light guiding portion 12 and the incident surface 16 of the first light guiding portion 11 are connected, and both are continuous, but the present invention is not limited to this configuration. As shown in FIG. 7, in another embodiment, the reflecting surface 18 of the second light guiding portion 12 and the incident surface 16 of the first light guiding portion 11 may be discontinuous. In addition, since the reflective surface 18 of the second light guide portion 12 is inclined, the end portion of the reflective surface 18 on the first light guide portion 11 side is brought closer to the incident surface 16 to obtain the first light guide portion 11. The area | region where light injects into the 2nd light guide part 12 can be expanded, and the light quantity of the light which injects into the 2nd light guide part 12 can be increased.

  As mentioned above, although the specific example of this invention was described in detail, these are only an illustration and do not limit a claim. The art set forth in the claims includes various variations and modifications of the specific examples illustrated above. The technical elements described in the present specification or the drawings exhibit technical usefulness singly or in various combinations, and are not limited to the combinations described in the claims at the time of application. In addition, the techniques exemplified in the present specification or the drawings can simultaneously achieve a plurality of purposes, and achieving one of the purposes itself has technical utility.

1: gas meter 2: main body 3: cover 10: main light 11: first light guide 12: second light guide 15: through hole 16: incident surface 17: output surface 18: reflective surface 21: counter 22: substrate 23: numeral car 25: inflow tube 26: outflow tube 31: light source 32: switch 34: opening for button 35: opening for light guide 39: power supply 40: return button 41: shaft portion 42: cover portion 70: secondary light guide Body 71: entrance surface 72: exit surface 75: through hole

Claims (4)

A gas meter comprising a light source that emits light when the gas supply is shut off, and a return button for returning the shut off gas supply,
A light guide for guiding the light of the light source around the return button;
The first light guide guiding the light of the light source into the light guide and the second light guide guiding the light passing through the first light guide around the return button Have
The first light guiding portion includes an incident surface facing the light source side,
The second light guide portion includes an emission surface facing the side opposite to the light incident surface, and a reflective surface facing the light incident surface side.
The gas meter in which the reflecting surface is inclined so as to move away from the exit surface and approach the incident surface as approaching the first light guide.   The gas meter according to claim 1, wherein the reflection surface and the incident surface are connected. A light guide for use in a gas meter comprising a light source which emits light when the gas supply is shut off, and a return button for returning the shut off gas supply,
A first light guide unit for guiding the light of the light source to the inside of the light guide;
And a second light guide for guiding the light having passed through the first light guide around the return button,
The first light guiding portion includes an incident surface facing the light source side,
The second light guide portion includes an emission surface facing the side opposite to the light incident surface, and a reflective surface facing the light incident surface side.
The light guide according to claim 1, wherein the reflecting surface is inclined so as to move away from the exit surface and approach the incident surface as approaching the first light guide. The light guide according to claim 3, wherein the reflecting surface and the incident surface are connected.