JP2014235073A - Nondirectional normally-open type compact vibration sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a nondirectional normally-open type compact vibration sensor extremely simple in structure and capable of detecting vibration in all directions with high accuracy.SOLUTION: The nondirectional normally-open type compact vibration sensor includes: a cylindrical body 10 which is a molded insulator; a pair of substantially convex fixed electrodes 20A, 20B fitted to upper and lower openings 13, 14 of a cylinder hole 11 in upper/lower symmetry with tip ends opposing each other at a predetermined spacing and constituting a lid body which air-tightly seals the cylinder hole; and a conductive electric bulb 30 housed to allow free rotation inside a vacant chamber 16 defined by the fixed electrodes and an inner wall 15 of the cylinder hole. The inner wall 15 of the vacant chamber is provided with at least one or more projection strips 17 slightly projected inward in a cross sectional radial direction. The conductive electric bulb 30 contacts with only one of the upper and lower fixed electrodes 20A and 20B in a static state so that both electrodes are made non-conductive, and when vibrated, regardless of the vibration direction, the conductive electric bulb 30 is pushed inward in the radial direction by the projection strips 17 to contact with both fixed electrodes 20A, 20B, and make the fixed electrodes conduct with each other.

Description

  The present invention relates to a vibration sensor, and more particularly to a small-sized vibration sensor that is incorporated in home appliances, electronic devices, and other precision devices to electrically detect vibrations of these products and devices.

  In the past, there were many small vibration sensors of this type that could only detect vibrations in a specific direction, but recently, so-called omnidirectional vibration sensors that can detect vibrations in all directions have emerged. .

  However, in such an omnidirectional vibration sensor, for example, as described in JP-A-10-21804 (Patent Document 1) and JP-A-10-154451 (Patent Document 2), In general, the number of parts required for the structure is large, and various assembly processes are required. Therefore, the labor and time required for the assembly process increase, and it is difficult to keep the manufacturing cost low. Therefore, it is difficult to promote downsizing in response to downsizing of various electronic devices as devices to be used in recent times, and vibrations frequently occur with walking, golf, and other exercises. When it is used in a small portable device such as an electronic wristwatch or a device with a lot of vibration, it is caused by a collision with a structural part of a conductive sphere that repeatedly moves and moves with the vibration. The Erareru impact or the like, damage to the spherical surface of the sphere, there is a problem that tends to cause deformation or displacement such sensitivity failure to malfunction or premature wear of the contact portion of the electrode member.

  In order to solve the above-mentioned problems, the applicant of the present application has a simple and identical configuration as an electrode member among conductive spheres, electrode members and attachment means as movable electrodes which are indispensable components for the configuration. Two electrode members, one mounting insulator or non-conductive cylindrical body as a single unit, and a total of only three parts are component parts of a single sensor, making the structure extremely simple, strong and reliable A highly omnidirectional normally closed small vibration sensor has been invented (for example, Patent Documents 3 and 4).

  However, in a normally closed type (normally closed) small vibration sensor, since the switch is always turned on, power such as a battery is always consumed, which is uneconomical. On the other hand, in this kind of omnidirectional compact vibration sensor, since it is necessary to increase the detection sensitivity of vibration, the normally closed type is generally used. It was difficult.

  For example, Patent Document 5 (Japanese Patent Laid-Open No. 2000-21277) discloses a normally open small vibration sensor. In the normally open small vibration sensor of Patent Document 5, in the stationary state, the conductive sphere is in contact with the bottom surface of the second electrode forming the slip-like inclined surface. By energizing the first electrode by going up the inclined surface, the switch is turned on.

JP 10-21804 A JP-A-10-154451 JP 2003-161653 A JP2003-151415A JP 2000-21277 A

  However, in the small vibration sensor described above, since the conductive sphere needs to abut along the peripheral surface of the first electrode in order to turn on the switch, the vibration sensor is not resistant to vibration in the horizontal direction or only in a specific direction. Although it can be detected, there is a drawback that it cannot detect vibrations in other directions. In addition, when the vibration is fine, the conductive sphere does not reach the first electrode and is difficult to detect. Further, in the vibration sensor, since the internal structure has few curved surfaces, both the conductive sphere and the electrode are easily fatigued by the impact received by the collision of the conductive sphere due to vibration, and there is a problem in terms of durability.

  The present invention has been made in view of the above-mentioned problems of the prior art. The present invention minimizes the number of components and makes the structure extremely simple, facilitating assembly work, and the whole. It can be miniaturized, can be offered at a low price by increasing mass productivity, and has excellent durability and wear resistance. At the same time, it is omnidirectional capable of highly accurate detection of vibrations in all directions. It is a main object of the present invention to provide a normally open type small vibration sensor.

  In order to achieve the above object, a first feature of the omnidirectional normally open type small vibration sensor according to the present invention is a molded insulator having a cylindrical hole having a substantially circular cross section that penetrates and opens in both upper and lower surfaces. A substantially convex portion that forms a lid body that fits the cylindrical body and the top and bottom openings of the cylindrical hole in a form that is vertically opposed to each other while maintaining a predetermined width interval and hermetically seals the cylindrical hole. A pair of fixed electrodes, and a conductive light bulb that is freely rolled and accommodated in an empty space defined by the fixed electrodes and the inner wall of the cylindrical hole. Provided with at least one ridge that protrudes slightly inward in the radial direction, the conductive sphere is in contact with only one of the fixed electrodes in a stationary state and is not electrically connected between the two fixed electrodes In addition, when vibrated, the conductive sphere is guided by the ridges regardless of the vibration direction, Ridges by contact with the two fixed electrodes are pushed radially inward and is characterized by being configured so as to turn the fixed electrode each other.

  A second feature of the omnidirectional normally open type small vibration sensor according to the present invention is that the cross section of the protruding portion in the first feature is formed by an arc having a predetermined radius. It is characterized by that.

  Furthermore, a third feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the fixed electrode in the first or second feature has a contour from the tip to the neck. It is characterized in that it is formed so as to draw a circular arc-shaped curve toward the end of the part and spread out at the bottom.

  Furthermore, a fourth feature of the omnidirectional normally open small vibration sensor according to the present invention is that the vacancy in any one of the first to third features is formed in a substantially donut shape. It is characterized by.

  The fifth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the diameter of the conductive sphere in any one of the first to fourth features is a stationary state in the empty room. It is characterized in that it is formed so as to be higher than the tip of the one fixed electrode.

  Furthermore, a sixth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the ridges in any one of the first to fifth features are provided at three locations at equal intervals in the empty chamber. It is formed as described above.

  Furthermore, a seventh feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the cylindrical hole in any one of the first to sixth features has an egg whose center is vertically long in the center. The upper and lower openings communicating with the central portion are formed so as to be fitted to the neck portion of the fixed electrode.

  Further, an eighth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the cylindrical body in any one of the first to seventh features is made of a heat-resistant synthetic resin. It is characterized by being molded.

  A ninth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that a plurality of the conductive spheres according to any one of the first to eighth features are accommodated. It is what.

  According to the present invention, when vibration is applied to the sensor without consuming wasteful power as in the normally closed type, the conductive sphere contacts both electrodes and conducts regardless of the vibration direction, and motion detection is performed. Can be performed omnidirectionally, thereby realizing a non-directional normally open vibration sensor that enables activation of the device to be used.

  In addition, the simple structure with few components not only makes it easy to attach the electrode members that occupy most of the assembly work, but also makes the structure extremely simple and strong, greatly reducing the overall size. In addition, it is possible to provide an inexpensive omnidirectional normally open vibration sensor that can be provided at low cost by increasing mass productivity, and has high durability and wear resistance, and at the same time has high reliability.

1 is a perspective view of a omnidirectional normally open type small vibration sensor 1. FIG. It is the longitudinal cross-sectional view which made the vibration sensor 1 a cross section along the AA 'line of FIG. It is the cross-sectional view which made the vibration sensor 1 a cross section along the BB 'line of FIG. It is the longitudinal cross-sectional view which made the vibration sensor 1 a cross section along the CC 'line of FIG. It is a three-dimensional view showing the internal state of the vibration sensor 1 when the cylindrical body 10 is cross-sectioned along the line DD ′. It is a longitudinal cross-sectional view at the time of making the cylindrical body 10 into a cross section along an AA 'line. It is a cross-sectional view of the vibration sensor 1 showing a state in which the fixed electrodes 20A and 20B are conductive (switches are turned on). It is an AA 'line longitudinal cross-sectional view of the vibration sensor 1 which shows the state which the fixed electrode has conduct | electrically_connected (switch is turned on).

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings, focusing on the following examples.

  FIG. 1 shows an omnidirectional normally open type small vibration sensor 1 as one embodiment of the present invention. FIG. 1 is a perspective view of the vibration sensor 1, and FIG. 2 is taken along the line AA 'of FIG. 3 is a longitudinal sectional view of the vibration sensor 1 taken along the line, FIG. 3 is a transverse sectional view of the vibration sensor 1 taken along the line BB ′ of FIG. 2, and FIG. 4 is taken along the line CC ′ of FIG. FIG. 5 is a three-dimensional perspective view of the cylindrical body showing the internal state of the vibration sensor 1, and FIG. 6 is a three-dimensional perspective view of the cylindrical body along AA ′. FIG. 7 is a transverse sectional view showing the case where the vibration sensor 1 is conducting, and FIG. 8 is a longitudinal sectional view taken along line AA ′ showing the state where the vibration sensor 1 is conducting.

  In these drawings, reference numeral 10 denotes a cylindrical tubular body. The tubular body 10 is integrally formed of a heat-resistant synthetic resin or the like, or a molded insulator such as glass or a non-conductive substance. Moreover, it has the cylindrical hole 11 of the cross-sectional substantially circular shape penetrated and opened on both upper and lower surfaces.

  The cylindrical hole 11 is formed in an oval elliptical shape with a central portion 12 having a vertically long cross section, and upper and lower openings 13 and 14 communicating with the central portion are fixed electrode members 20A and 20B. The neck portions 21A and 21B are formed so as to be fitted.

  The fixed electrodes 20A and 20B are a pair of electrode members having the same shape and dimensions, and are formed in a substantially convex shape with a vertical cross section of 360 degrees in the horizontal direction. In the fixed electrodes 20A and 20B, the contours 23A and 23B from the projecting tip portions 22A and 22B to the disc-shaped neck portions 21A and 21B draw an arcuate curve toward the ends of the neck portions 21A and 21B. It is formed so that the hem spreads.

  The fixed electrodes 20A and 20B are fitted and fixed to the upper opening 13 and the lower opening 14 of the cylindrical hole 11 so as to be vertically symmetrical with the tip portions 22A and 22B facing each other with an interval of a predetermined width, A lid that hermetically seals the cylindrical hole 11 is configured. In addition, the diameters of the upper and lower openings 13 and 14 are substantially matched with the diameters of the neck portions 21A and 21B of the fixed electrodes 20A and 20B.

  When the pair of fixed electrodes 20 </ b> A and 20 </ b> B are fixed to the cylindrical body 10, an empty chamber 16 is defined by the electrodes 20 </ b> A and 20 </ b> B and the inner wall 15 of the cylindrical hole 11. The inner wall 15 is formed in a substantially hemispherical concave shape in the longitudinal section. In addition, a conductive light bulb 30 is housed inside the empty room 16 so as to be freely rollable.

  The inner wall 15 of the vacant chamber 16 is formed with ridges 17 projecting slightly inward in the radial direction of the cross section from the upper part to the lower part of the inner wall 15, and in the example shown in the figure, three are provided at equal intervals. ing. The ridge portion 17 is formed in an arc having a predetermined radius in the cross section, and is smoothly continuous with the peripheral edge portion of the other inner wall 15 by a curve. In addition, the said protruding item | line part 17 should just be one or more places, and a number is not specifically limited.

  In the illustrated example, each of the electrodes 20A and 20B is a brass block formed by pressing into the same shape and dimensions, and the entire surface thereof has a conductive film such as gold plating (see FIG. (Not shown). In addition, the conductive sphere 30 which is a metal sphere is obtained by applying a conductive coating such as gold plating to the entire surface of, for example, a tungsten sphere, a stainless sphere, a steel sphere or the like. As a result, conductivity is improved and corrosion is prevented.

  Further, in the illustrated example, the cylindrical body 10 has a high heat distortion temperature and is excellent in heat-resistant dimensional stability, and is an injection molding machine from PPS resin and other engineering plastics that are rich in mass productivity. It is molded all in one piece. The cylindrical body 10 may have a rectangular shape or a rectangular shape in addition to a cylindrical shape.

  The diameter of the conductive sphere 30 is smaller than the length of the short axis from the center of the vacant space 16 to the inner wall 15 in FIG. 3 and larger than the length of the line segment that bisects the short axis. When in the chamber 16, it is formed so as to be higher than the tip 22A of the fixed electrode 20A. In addition, one conductive sphere 30 is accommodated in the empty chamber 16 in the illustrated example, but a plurality of conductive spheres 30 may be accommodated. When there are a plurality of conductive spheres 30, the conductive spheres 30 may be formed slightly smaller than in the case of one. It is desirable that the size and number of the conductive spheres 30 are appropriately adjusted according to the degree of vibration detection accuracy.

  The vibration sensor 1 according to the present invention is configured as a normally open type, that is, a normally open type vibration sensor, and when the vibration sensor 1 is in a horizontal state, as shown in FIGS. 30 abuts only on the upper surface of the neck portion 21A of the fixed electrode 20A, and the fixed electrode 20A and the fixed electrode 20B are in an open state, that is, a non-conductive state.

  When vibration is applied to the vibration sensor 1, the conductive sphere 30 jumps in the empty chamber 16, violently rolls left and right, or rotates along the inner wall 15 along the circumferential direction. To do. At this time, when the conductive sphere 30 rides on or collides with the ridges 17, the conductive spheres 30 are guided by the ridges 17 and pushed out radially inward, as shown in FIG. As shown in FIG. 8, both the fixed electrodes 20A and 20B come into contact with the tip portions 22A and 22B, the electrode 20A and 20B are closed, and the switch circuit is turned on. That is, the convex portion 17 increases the accuracy of vibration detection.

  Further, since the inner wall 15 of the vacant chamber 16 has a hemispherical concave shape, and the contours 23A and 23B of the electrodes 20A and 20B are formed in an arc shape, the vacant chamber 16 forms a substantially donut shape, and the sensor In addition to smooth rolling of the conductive sphere 30 when 1 vibrates, even if the sphere 30 jumps or bounces and collides with the inner wall 15, the ridge 17 or the contours 23A and 23B, Since the contact between the two at the time of the collision becomes a contact with the hemispherical concave surface or the convex hemispherical surface, the local impact at the time of the collision is weakened. Further, there is no repeated contact at a specific location. Therefore, the gold-plated layer on the electrode side and the sphere side is hardly damaged, and the occurrence of uneven deformation of the tip portions 21A and 21B as contact portions on the electrode side can be effectively prevented. It is possible to prevent the early occurrence of contact failure caused by scratches.

  The illustrated sensor can be directly soldered to a printed circuit board or the like, but the outer ends of the circular neck portions 21A and 21B of each electrode are appropriately processed, and terminals are respectively attached to the processed portions (not shown). It is also possible to connect the power supply circuit via the terminal.

  In the omnidirectional normally open type small inclination sensor 1 in the present embodiment, the height is about 2.1 mm and the diameter width is about 4.5 mm. In that case, the maximum diameter of the vacant chamber 16 in FIG. 3 is about 3.4 mm, the diameter of the top of the fixed electrode 20A is about 0.4 mm, and the arc of the ridge 17 has a radius of about 1.7 mm. Is formed of things. In addition, the said dimension is an example of the omnidirectional normally open small inclination sensor 1 which concerns on this invention, Comprising: It can change suitably by a design change. For example, the omnidirectional normally open type small inclination sensor 1 itself may be further reduced in size. For example, it may be formed with a height of about 1.9 mm and a diameter width of about 3.6 mm.

  Since the present invention is configured as described above, a conductive sphere as a movable electrode, two simple electrode members having the same configuration as an electrode member, and a molded insulator or non-conductive cylindrical body as a single body. Only one part, a total of three parts, is required as a component of the sensor body. Not only is the electrode member that occupies most of the assembly work easy to install, but the structure is also very simple and robust. The overall size can be greatly reduced, the mass productivity can be increased and the product can be offered at a low price, and it is highly durable and wear-resistant, and at the same time has a highly reliable omnidirectionality. A normally open small vibration sensor can be obtained.

  The embodiments of the present invention have been described in detail with reference to the drawings and tables. However, the present invention is not limited thereto, and can be implemented in various modes within the scope of the configurations described in the claims. it can.

  According to the present invention, it is possible to detect vibrations of such products and devices by being incorporated in general home appliances and electronic devices. In particular, smartphones and touch-panel portable terminals do not use unnecessary power when not in use, allowing power savings and reducing the frequency of charging, etc. However, it can be used immediately without pressing any other key. That is, only when the device is used, the switch of the device to be used is automatically turned on, so that battery consumption can be prevented and power saving can be achieved.

DESCRIPTION OF SYMBOLS 1 Non-directional normally open small vibration sensor 10 Cylindrical body 11 Cylindrical hole 15 Inner wall 16 Vacant room 17 Projection part 20A, 20B Fixed electrode 30 Conductive sphere

  The present invention relates to a vibration sensor, and more particularly to a small-sized vibration sensor that is incorporated in home appliances, electronic devices, and other precision devices to electrically detect vibrations of these products and devices.

  In the past, there were many small vibration sensors of this type that could only detect vibrations in a specific direction, but recently, so-called omnidirectional vibration sensors that can detect vibrations in all directions have emerged. .

  However, in such an omnidirectional vibration sensor, for example, as described in JP-A-10-21804 (Patent Document 1) and JP-A-10-154451 (Patent Document 2), In general, the number of parts required for the structure is large, and various assembly processes are required. Therefore, the labor and time required for the assembly process increase, and it is difficult to keep the manufacturing cost low. Therefore, it is difficult to promote downsizing in response to downsizing of various electronic devices as devices to be used in recent times, and vibrations frequently occur with walking, golf, and other exercises. When it is used in a small portable device such as an electronic wristwatch or a device with a lot of vibration, it is caused by a collision with a structural part of a conductive sphere that repeatedly moves and moves with the vibration. The Erareru impact or the like, damage to the spherical surface of the sphere, there is a problem that tends to cause deformation or displacement such sensitivity failure to malfunction or premature wear of the contact portion of the electrode member.

  In order to solve the above-mentioned problems, the applicant of the present application has a simple and identical configuration as an electrode member among conductive spheres, electrode members and attachment means as movable electrodes which are indispensable components for the configuration. Two electrode members, one mounting insulator or non-conductive cylindrical body as a single unit, and a total of only three parts are component parts of a single sensor, making the structure extremely simple, strong and reliable A highly omnidirectional normally closed small vibration sensor has been invented (for example, Patent Documents 3 and 4).

  However, in a normally closed type (normally closed) small vibration sensor, since the switch is always turned on, power such as a battery is always consumed, which is uneconomical. On the other hand, in this kind of omnidirectional compact vibration sensor, since it is necessary to increase the detection sensitivity of vibration, the normally closed type is generally used. It was difficult.

  For example, Patent Document 5 (Japanese Patent Laid-Open No. 2000-21277) discloses a normally open small vibration sensor. In the normally open small vibration sensor of Patent Document 5, in the stationary state, the conductive sphere is in contact with the bottom surface of the second electrode forming the slip-like inclined surface. By energizing the first electrode by going up the inclined surface, the switch is turned on.

JP 10-21804 A JP-A-10-154451 JP 2003-161653 A JP2003-151415A JP 2000-21277 A

  However, in the small vibration sensor described above, since the conductive sphere needs to abut along the peripheral surface of the first electrode in order to turn on the switch, the vibration sensor is not resistant to vibration in the horizontal direction or only in a specific direction. Although it can be detected, there is a drawback that it cannot detect vibrations in other directions. In addition, when the vibration is fine, the conductive sphere does not reach the first electrode and is difficult to detect. Further, in the vibration sensor, since the internal structure has few curved surfaces, both the conductive sphere and the electrode are easily fatigued by the impact received by the collision of the conductive sphere due to vibration, and there is a problem in terms of durability.

  The present invention has been made in view of the above-mentioned problems of the prior art. The present invention minimizes the number of components and makes the structure extremely simple, facilitating assembly work, and the whole. It can be miniaturized, can be offered at a low price by increasing mass productivity, and has excellent durability and wear resistance. At the same time, it is omnidirectional capable of highly accurate detection of vibrations in all directions. It is a main object of the present invention to provide a normally open type small vibration sensor.

In order to achieve the above object, a first feature of the omnidirectional normally open type small vibration sensor according to the present invention is a molded insulator having a cylindrical hole having a substantially circular cross section that penetrates and opens in both upper and lower surfaces. The horizontal direction 360 which comprises a cylindrical body and the top and bottom opening of this cylinder hole fitted in the aspect which faced up and down symmetrically with the front-end | tip facing a slight space | interval, and comprises the cover body which airtightly seals this cylinder hole A pair of fixed electrodes having a substantially convex shape in a longitudinal section , and the fixed electrode and an inner wall formed in a concave shape in a substantially hemispherical shape in the longitudinal section of the cylindrical body, and are freely rolled. A conductive light bulb, and the fixed electrode has an arcuate curve extending from the tip to the neck to form an arc-shaped curve toward the end of the neck, together with the inner wall of the cylindrical body it is formed in a substantially annular vertical section a substantially circular or substantially elliptical said air chamber and the inner wall of the tubular body The cross section arcuate ridge which slightly protrusion to smoothly cross section radially inwardly continuously a curve comprise at least one place or more, the conductive spheres of the fixed electrode is at rest Contacting only one side to make the two fixed electrodes non-conductive, and when vibrating, rolls in a substantially circular or elliptical vacant space regardless of the vibration direction , or the ridges It is configured to be pushed out inward in the radial direction by the portion so as to come into contact with both the fixed electrodes and to connect the fixed electrodes to each other.

The second feature of the omnidirectional normally-open small vibration sensor according to the present invention according to the present invention is that the diameter of the conductive sphere in the first feature is determined when the diameter of the conductive sphere is stationary in the empty room. It is characterized by being formed so as to be higher than the tip of one fixed electrode .

Furthermore, a third feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the ridges in the first or second feature are provided at three locations at equal intervals in the empty chamber. It is formed as described above .

Furthermore, a fourth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the cylindrical hole in any one of the first to third features has an egg whose center is vertically long in the center. The upper and lower openings communicating with the central portion are formed so as to be fitted to the neck portion of the fixed electrode .

The fifth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that the cylindrical body in any one of the first to fourth features is made of a heat-resistant synthetic resin. It is characterized by being molded .

Furthermore, a sixth feature of the omnidirectional normally-open small vibration sensor according to the present invention is that a plurality of the conductive spheres according to any one of the first to fifth features are accommodated. It is what.

  According to the present invention, when vibration is applied to the sensor without consuming wasteful power as in the normally closed type, the conductive sphere contacts both electrodes and conducts regardless of the vibration direction, and motion detection is performed. Can be performed omnidirectionally, thereby realizing a non-directional normally open vibration sensor that enables activation of the device to be used.

  In addition, the simple structure with few components not only makes it easy to attach the electrode members that occupy most of the assembly work, but also makes the structure extremely simple and strong, greatly reducing the overall size. In addition, it is possible to provide an inexpensive omnidirectional normally open vibration sensor that can be provided at low cost by increasing mass productivity, and has high durability and wear resistance, and at the same time has high reliability.

1 is a perspective view of a omnidirectional normally open type small vibration sensor 1. FIG. It is the longitudinal cross-sectional view which made the vibration sensor 1 a cross section along the AA 'line of FIG. It is the cross-sectional view which made the vibration sensor 1 a cross section along the BB 'line of FIG. It is the longitudinal cross-sectional view which made the vibration sensor 1 a cross section along the CC 'line of FIG. It is a three-dimensional view showing the internal state of the vibration sensor 1 when the cylindrical body 10 is cross-sectioned along the line DD ′. It is a longitudinal cross-sectional view at the time of making the cylindrical body 10 into a cross section along an AA 'line. It is a cross-sectional view of the vibration sensor 1 showing a state in which the fixed electrodes 20A and 20B are conductive (switches are turned on). It is an AA 'line longitudinal cross-sectional view of the vibration sensor 1 which shows the state which the fixed electrode has conduct | electrically_connected (switch is turned on).

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings, focusing on the following examples.

  FIG. 1 shows an omnidirectional normally open type small vibration sensor 1 as one embodiment of the present invention. FIG. 1 is a perspective view of the vibration sensor 1, and FIG. 2 is taken along the line AA 'of FIG. 3 is a longitudinal sectional view of the vibration sensor 1 taken along the line, FIG. 3 is a transverse sectional view of the vibration sensor 1 taken along the line BB ′ of FIG. 2, and FIG. 4 is taken along the line CC ′ of FIG. FIG. 5 is a three-dimensional perspective view of the cylindrical body showing the internal state of the vibration sensor 1, and FIG. 6 is a three-dimensional perspective view of the cylindrical body along AA ′. FIG. 7 is a transverse sectional view showing the case where the vibration sensor 1 is conducting, and FIG. 8 is a longitudinal sectional view taken along line AA ′ showing the state where the vibration sensor 1 is conducting.

  In these drawings, reference numeral 10 denotes a cylindrical tubular body. The tubular body 10 is integrally formed of a heat-resistant synthetic resin or the like, or a molded insulator such as glass or a non-conductive substance. Moreover, it has the cylindrical hole 11 of the cross-sectional substantially circular shape penetrated and opened on both upper and lower surfaces.

  The cylindrical hole 11 is formed in an oval elliptical shape with a central portion 12 having a vertically long cross section, and upper and lower openings 13 and 14 communicating with the central portion are fixed electrode members 20A and 20B. The neck portions 21A and 21B are formed so as to be fitted.

  The fixed electrodes 20A and 20B are a pair of electrode members having the same shape and dimensions, and are formed in a substantially convex shape with a vertical cross section of 360 degrees in the horizontal direction. In the fixed electrodes 20A and 20B, the contours 23A and 23B from the projecting tip portions 22A and 22B to the disc-shaped neck portions 21A and 21B draw an arcuate curve toward the ends of the neck portions 21A and 21B. It is formed so that the hem spreads.

The fixed electrodes 20A and 20B are fitted and fixed to the upper opening 13 and the lower opening 14 of the cylindrical hole 11 so as to be vertically symmetrical with the tip portions 22A and 22B facing each other with a slight gap therebetween. A lid that hermetically seals the hole 11 is configured. In addition, the diameters of the upper and lower openings 13 and 14 are substantially matched with the diameters of the neck portions 21A and 21B of the fixed electrodes 20A and 20B.

When the pair of fixed electrodes 20 </ b> A and 20 </ b> B are fixed to the cylindrical body 10, an empty chamber 16 is defined by the electrodes 20 </ b> A and 20 </ b> B and the inner wall 15 of the cylindrical body 10 . The inner wall 15 is formed in a substantially hemispherical concave shape in the longitudinal section. In addition, a conductive light bulb 30 is housed inside the empty room 16 so as to be freely rollable.

The inner wall 15 of the cylindrical body 10 is formed with ridges 17 that slightly protrude inward in the radial direction of the cross section from the upper part to the lower part of the inner wall 15. In the illustrated example, three parts are provided at equal intervals. It has been. The ridge portion 17 is formed in an arc having a predetermined radius in the cross section, and is smoothly continuous with the peripheral edge portion of the other inner wall 15 by a curve. In addition, the said protruding item | line part 17 should just be one or more places, and a number is not specifically limited.

  In the illustrated example, each of the electrodes 20A and 20B is a brass block formed by pressing into the same shape and dimensions, and the entire surface thereof has a conductive film such as gold plating (see FIG. (Not shown). In addition, the conductive sphere 30 which is a metal sphere is obtained by applying a conductive coating such as gold plating to the entire surface of, for example, a tungsten sphere, a stainless sphere, a steel sphere or the like. As a result, conductivity is improved and corrosion is prevented.

  Further, in the illustrated example, the cylindrical body 10 has a high heat distortion temperature and is excellent in heat-resistant dimensional stability, and is an injection molding machine from PPS resin and other engineering plastics that are rich in mass productivity. It is molded all in one piece. The cylindrical body 10 may have a rectangular shape or a rectangular shape in addition to a cylindrical shape.

  The diameter of the conductive sphere 30 is smaller than the length of the short axis from the center of the vacant space 16 to the inner wall 15 in FIG. 3 and larger than the length of the line segment that bisects the short axis. When in the chamber 16, it is formed so as to be higher than the tip 22A of the fixed electrode 20A. In addition, one conductive sphere 30 is accommodated in the empty chamber 16 in the illustrated example, but a plurality of conductive spheres 30 may be accommodated. When there are a plurality of conductive spheres 30, the conductive spheres 30 may be formed slightly smaller than in the case of one. It is desirable that the size and number of the conductive spheres 30 are appropriately adjusted according to the degree of vibration detection accuracy.

  The vibration sensor 1 according to the present invention is configured as a normally open type, that is, a normally open type vibration sensor, and when the vibration sensor 1 is in a horizontal state, as shown in FIGS. 30 abuts only on the upper surface of the neck portion 21A of the fixed electrode 20A, and the fixed electrode 20A and the fixed electrode 20B are in an open state, that is, a non-conductive state.

  When vibration is applied to the vibration sensor 1, the conductive sphere 30 jumps in the empty chamber 16, violently rolls left and right, or rotates along the inner wall 15 along the circumferential direction. To do. At this time, when the conductive sphere 30 rides on or collides with the ridges 17, the conductive spheres 30 are guided by the ridges 17 and pushed out radially inward, as shown in FIG. As shown in FIG. 8, both the fixed electrodes 20A and 20B come into contact with the tip portions 22A and 22B, the electrode 20A and 20B are closed, and the switch circuit is turned on. That is, the convex portion 17 increases the accuracy of vibration detection.

Further, the inner wall 15 of the tubular body 10 has a hemispherical concave shape, and the outlines 23A and 23B of the electrodes 20A and 20B are formed in an arc shape, so that the vacant chamber 16 has a substantially circular or substantially elliptical cross section. forming a substantially annular in form, the rolling of the conductive spheres 30 when the sensor 1 is vibrated Ri is Do smoothly, two fixed electrodes 20A, rather than Rubakari an easy contact with 20B, the sphere 30 is Even if it jumps or bounces and collides with the inner wall 15, the ridge 17 or the contours 23A and 23B, the contact between the two at the time of the collision is a contact with the hemispherical concave surface or the convex rim hemisphere. The local impact is reduced. Further, there is no repeated contact at a specific location. Therefore, the gold-plated layer on the electrode side and the sphere side is hardly damaged, and the occurrence of uneven deformation of the tip portions 21A and 21B as contact portions on the electrode side can be effectively prevented. It is possible to prevent the early occurrence of contact failure caused by scratches.

  The illustrated sensor can be directly soldered to a printed circuit board or the like, but the outer ends of the circular neck portions 21A and 21B of each electrode are appropriately processed, and terminals are respectively attached to the processed portions (not shown). It is also possible to connect the power supply circuit via the terminal.

  In the omnidirectional normally open type small inclination sensor 1 in the present embodiment, the height is about 2.1 mm and the diameter width is about 4.5 mm. In that case, the maximum diameter of the vacant chamber 16 in FIG. 3 is about 3.4 mm, the diameter of the top of the fixed electrode 20A is about 0.4 mm, and the arc of the ridge 17 has a radius of about 1.7 mm. Is formed of things. In addition, the said dimension is an example of the omnidirectional normally open small inclination sensor 1 which concerns on this invention, Comprising: It can change suitably by a design change. For example, the omnidirectional normally open type small inclination sensor 1 itself may be further reduced in size. For example, it may be formed with a height of about 1.9 mm and a diameter width of about 3.6 mm.

  Since the present invention is configured as described above, a conductive sphere as a movable electrode, two simple electrode members having the same configuration as an electrode member, and a molded insulator or non-conductive cylindrical body as a single body. Only one part, a total of three parts, is required as a component of the sensor body. Not only is the electrode member that occupies most of the assembly work easy to install, but the structure is also very simple and robust. The overall size can be greatly reduced, the mass productivity can be increased and the product can be offered at a low price, and it is highly durable and wear-resistant, and at the same time has a highly reliable omnidirectionality. A normally open small vibration sensor can be obtained.

  The embodiments of the present invention have been described in detail with reference to the drawings and tables. However, the present invention is not limited thereto, and can be implemented in various modes within the scope of the configurations described in the claims. it can.

  According to the present invention, it is possible to detect vibrations of such products and devices by being incorporated in general home appliances and electronic devices. In particular, smartphones and touch-panel portable terminals do not use unnecessary power when not in use, allowing power savings and reducing the frequency of charging, etc. However, it can be used immediately without pressing any other key. That is, only when the device is used, the switch of the device to be used is automatically turned on, so that battery consumption can be prevented and power saving can be achieved.

DESCRIPTION OF SYMBOLS 1 Non-directional normally open small vibration sensor 10 Cylindrical body 11 Cylindrical hole 15 Inner wall 16 Vacant room 17 Projection part 20A, 20B Fixed electrode 30 Conductive sphere

Claims (9)

A cylindrical body, which is a molded insulator having a cylindrical hole having a substantially circular cross section that opens through both the upper and lower surfaces, and a vertical end of the cylindrical hole facing the upper and lower openings symmetrically with a predetermined width therebetween. In a closed state defined by a pair of substantially convex fixed electrodes that form a lid that hermetically seals the cylindrical hole and the fixed electrode and the inner wall of the cylindrical hole. A conductive bulb that is freely movable, and the inner wall of the vacant chamber has at least one protruding portion that slightly protrudes inward in the radial direction of the cross section. In a stationary state, only one of the fixed electrodes is brought into contact and non-conducting between the two fixed electrodes, and when it vibrates, it is pushed out inward in the radial direction by the protrusions regardless of the vibration direction. That the fixed electrodes are in contact with each other, and the fixed electrodes are electrically connected to each other;
A omnidirectional normally open type small vibration sensor. The cross section of the ridge is formed by an arc having a predetermined radius;
The omnidirectional normally-open type small vibration sensor according to claim 1. The fixed electrode is formed so that the contour from the tip portion to the neck portion forms an arc-shaped curve toward the end portion of the neck portion and spreads at the bottom.
The omnidirectional normally open type small vibration sensor according to claim 1 or 2. The vacancy is formed in a substantially donut shape;
The omnidirectional normally open type small vibration sensor according to any one of claims 1 to 3. The diameter of the conductive sphere is formed to be higher than the tip of the one fixed electrode in a stationary state in the vacant chamber,
The omnidirectional normally open type small vibration sensor according to any one of claims 1 to 4. Three or more ridges are formed at equal intervals in the vacant space;
The omnidirectional normally open type small vibration sensor according to any one of claims 1 to 5. The cylindrical hole is formed in an oval elliptical shape with a vertically long cross section at the center, and upper and lower openings communicating with the center are fitted with the neck of the fixed electrode. Formed in the
The omnidirectional normally open type small vibration sensor according to any one of claims 1 to 6. The cylindrical body is formed integrally with a heat-resistant synthetic resin,
The omnidirectional normally open type small vibration sensor according to any one of claims 1 to 7. A plurality of the conductive spheres are stored;
The omnidirectional normally open type small vibration sensor according to any one of claims 1 to 8.

Images