JP6135930B2 - State detection device and buckle device using the same - Google Patents

Description

  The present invention relates to a state detection device and a buckle device using the same.

  The vehicle is provided with a seat belt device for restraining the seated occupant's body for safety. The webbing pulled out from the webbing take-up device of the seat belt device passes through a slit-like insertion hole formed in a through anchor provided above the center pillar of the vehicle, and is folded back to the vehicle lower side. It is fixed to an anchor provided in the vicinity of the winding device. Further, a tongue is provided on the webbing between the tip of the webbing fixed to the anchor and the folded part of the through anchor. The tongue plate of the tongue restrains the occupant's body by being inserted and held in the apparatus body of the buckle device.

  Here, the buckle device is provided with a state detection device for detecting that the tongue plate is inserted and held in the device main body. This state detection device detects a slide position state of the tongue plate in the buckle body, and is called a buckle switch. For example, a connector part that can be connected to a buckle switch of a seat belt buckle is provided, a control circuit that receives a detection signal from the buckle switch inside the connector part and judges whether a tongue is attached or detached, and a judgment result from this control circuit There is a vehicle seat belt detection device including a communication circuit that transmits a result signal based on a meter control unit connected via an in-vehicle network (see, for example, Patent Document 1).

  According to this buckle device, a vehicle seat belt detection device and a vehicle seat belt detection system capable of detecting attachment / detachment of a vehicle seat belt by communication via an in-vehicle network are described.

JP 2011-88580 A

  However, since the power of the buckle device shown above is supplied from the vehicle main body to the communication circuit in the buckle device via the harness, the degree of freedom in design of the buckle device is small, and the buckle device is used. The restriction of movement when doing so is a problem.

  Therefore, an object of the present invention is applicable to an apparatus having an independent power supply means, and a state detection apparatus having a switch structure suitable for ensuring an on-time of the state detection operation, and a buckle apparatus using the state detection apparatus. It is to provide.

  [1] In order to achieve the above object, according to the present invention, there is provided a substrate having a conductive pattern formed on a surface thereof, driven by a switch operation, and in contact with the surface of the substrate while moving relative to the substrate. A first slider provided with a contact, and the first slider and an elastic member connected to each other, and a relative movement while contacting the surface of the substrate with a phase difference with respect to the first slider by the switch operation And a second slider having a second contact, wherein the switch operation state is detected based on a conduction state between the first and second contacts and the conductive pattern. A detection device is provided.

  [2] The substrate has the conductive patterns on the front surface and the back surface, respectively, the first contact is in contact with the front surface, and the second contact is in contact with the back surface. 1] may be used.

  [3] The state detection device according to [1], wherein the substrate has the conductive pattern on one side, and the first contact and the second contact are in contact with the one side. It may be.

  [4] The state detection device according to any one of [1] to [3], wherein the elastic member is a coil spring.

  [5] The state detection device according to any one of [1] to [4], a communication control circuit that communicates a detection result of the state detection device, and power is supplied to the state detection device and the communication control circuit. And a power supply means for performing state detection.

  [6] In order to achieve the above object, the present invention is mounted on a device main body capable of inserting, holding, and discharging a tongue plate provided on a webbing of a seat belt device of a vehicle, and placed in the device main body. And a state detecting device according to [5], wherein the state detecting device detects the state of the tongue plate.

  [7] The buckle device according to [6], wherein the communication control circuit is supplied with power from the power supply means only when the tongue plate is inserted or ejected. Also good.

  [8] Further, the communication control circuit is supplied with power from the power supply means via the second contact, and the tongue plate is inserted by detecting a contact state between the first contact and the conductive pattern. The buckle device according to [6] or [7], wherein the buckle device performs detection of holding, discharging, and discharging.

  According to one aspect of the present invention, a state detection device having an independent power supply means, a state detection device having a switch structure suitable for securing an on-time of a state detection operation, and the same are used. A buckle device can be provided.

FIG. 1 is an exploded perspective view of a buckle device according to a first embodiment of the present invention. FIG. 2 is a cross-sectional view of the buckle device showing a state before the tongue plate is inserted into the buckle body. FIG. 3 is a three-dimensional perspective view of the buckle switch. FIG. 4 is a cross-sectional view along the slide movement direction of the buckle switch. FIG. 5A is a top plan view of the surface 30a of the substrate 30, and is a pattern diagram of the conductive pattern A with which the contact A 26 comes into contact. FIG. 5B is a side view of the substrate. FIG. 5C is a lower plan view of the back surface 30b of the substrate 30 and is a pattern diagram of the conductive pattern B with which the contact B 28 comes into contact. FIG. 6 is a block diagram of the buckle switch. FIG. 7 is a cross-sectional view of the buckle device showing a state in which the tongue plate is inserted into the buckle body. FIG. 8A (a) is a top plan view of the surface of the substrate showing a contact state between the conductive pattern A and the contact A on the surface of the substrate at t = 0. FIG. 8A (b) is a bottom plan view of the back surface of the substrate showing a contact state between the conductive pattern B and the contact B on the back surface of the substrate at t = 0. FIG. 8B (a) is an upper plan view of the surface of the substrate showing a contact state between the conductive pattern A and the contact A on the surface of the substrate at t = t ₁ . FIG. 8B (b) is a bottom plan view of the back surface of the substrate showing a contact state between the conductive pattern B and the contact B on the back surface of the substrate at t = t ₁ . Figure 8C (a) is at t = t _2, top plan view of the surface of the substrate showing a state of contact between the conductive pattern A and the contact A of the surface of the substrate. FIG. 8C (b) is a lower plan view of the back surface of the substrate showing a contact state between the conductive pattern B and the contact B on the back surface of the substrate at t = t ₂ . FIG. 8D (a) is an upper plan view of the surface of the substrate showing a contact state between the conductive pattern A and the contact A on the surface of the substrate at t = t ₃ . FIG. 8D (b) is a bottom plan view of the back surface of the substrate showing a contact state between the conductive pattern B and the contact B on the back surface of the substrate at t = t ₃ . Figure 8E (a) is at t = t _4, top plan view of the surface of the substrate showing a state of contact between the conductive pattern A and the contact A of the surface of the substrate. FIG. 8E (b) is a bottom plan view of the back surface of the substrate showing a contact state between the conductive pattern B and the contact B on the back surface of the substrate at t = t ₄ . Figure 8F (a) is at t = t _5, top plan view of the surface of the substrate showing a state of contact between the conductive pattern A and the contact A of the surface of the substrate. FIG. 8F (b) is a lower plan view of the back surface of the substrate showing a contact state between the conductive pattern B and the contact B on the back surface of the substrate at t = t ₅ . FIG. 9 is a characteristic diagram showing the sliding movement characteristics of the contacts A and B, that is, the relationship between the time t and the distance X. FIG. 10 is a cross-sectional view of the buckle switch according to the second embodiment along the slide movement direction. FIG. 11 is a top plan view of the surface of the substrate, and is a pattern diagram in which the contacts A and C which are the first and second contacts are in contact with each other. FIG. 12A is a top plan view of the surface of the substrate showing a contact state between the conductive pattern C on the surface of the substrate and the contacts A and C before the insertion of the tongue plate (at the time of discharging). FIG. 12B is an upper plan view of the surface of the substrate showing a contact state between the conductive pattern C on the surface of the substrate and the contacts A and C during the insertion of the tongue plate. FIG. 12C is a top plan view of the surface of the substrate showing a contact state between the conductive pattern C on the surface of the substrate and the contacts A and C when the tongue plate is completely inserted (held).

(First embodiment of the present invention)
(Configuration of buckle device and buckle switch)
FIG. 1 is an exploded perspective view of a buckle device 1 according to a first embodiment of the present invention. The buckle device 1 is a device main body capable of inserting and holding a tongue plate 130 provided on a webbing of a seat belt device of a vehicle, and a state detection device that is arranged in the device main body and detects a state of a slide position. A buckle switch 2.

  The buckle switch 2 includes a housing 201 that is a housing, a substrate 30 having a conductive pattern formed on the surface thereof, and a substrate 30 fixed to the housing 201, and a contact A 26 that contacts the surface of the substrate 30 while moving relative to the substrate 30. The slider A 25 is connected to the slider A 25 by a coil spring 29, and has a phase difference with respect to the slider A 25 by a switch operation (operations such as inserting and ejecting the tongue plate 130). And a slider B 27 having a contact B 28 that relatively moves while being in contact. The buckle switch 2 has a predetermined conductive pattern formed on the surface of the substrate 30 and is a state in which the switch operation state is detected by the conductive state between the contact A 26 and the conductive pattern A, and the contact B 28 and the conductive pattern B. Functions as a detection device.

  FIG. 2 is a cross-sectional view of the buckle device 1 showing a state before the tongue plate 130 is inserted into the buckle body. FIG. 3 is a three-dimensional perspective view of the buckle switch 2. FIG. 4 is a cross-sectional view of the buckle switch 2 along the slide movement direction.

  As shown in FIGS. 3 and 4, the slider A 25 as the first slider has a block shape formed by a slider A main body 25 a and a protruding portion 25 b provided protruding upward. One end of a coil spring 29 as an elastic member is fixed to one end of the slider A main body 25a in the sliding movement direction, and another coil spring 29 is fixed to the other end of the slider A main body 25a. A contact A 26 that is a first contact that contacts the conductive pattern A formed on the surface 30a of the substrate 30 is attached to the lower surface 25c of the slider A main body 25a. It is possible to slide along the surface 30a.

  The above-described coil springs 29 and 29 may be elastic members, and other shape springs, elastic rubber, elastic foam, and the like can be used in addition to the coil springs.

  As shown in FIG. 4, the protruding portion 25 b of the slider A 25 is fitted into a fitting hole 34 b formed in the protruding portion 34 a of the ejector 34 and moves integrally with the ejector 34. That is, it moves integrally with the ejector 34 in conjunction with operations such as insertion and ejection of the tongue plate 130.

  The contact A 26 is a metal (conductive) leaf spring, which is formed of a spring material having spring properties (spring steel, spring stainless steel, spring phosphor bronze, etc.), and has a predetermined surface on the substrate 30. The tip 26a comes into contact with pressure (pressing force). The slider A 25 is slidable along the surface 30a of the substrate 30 while maintaining this contact state.

  As shown in FIGS. 3 and 4, the slider B 27, which is the second slider, is connected to the slider A 25 by coil springs 29 and 29, and the slider A 25 is operated by a switch operation (an operation of inserting or ejecting the tongue plate 130). Relative to the substrate 30 while contacting the substrate 30.

  As shown in FIGS. 3 and 4, the slider B 27 is a block formed by a slider B main body 27 a and a protruding portion 27 b provided to protrude upward in order to fix the end portions of the coil springs 29 and 29. It is said that.

  A contact B 28, which is a second contact that contacts the conductive pattern B formed on the back surface 30 b, is attached to the surface 27 c where the slider B 27 faces the back surface 30 b of the substrate 30.

  Similarly to the contact A 26, the contact B 28 is a metal (conductive) leaf spring, and is formed of a spring material having spring properties (spring steel, spring stainless steel, spring phosphor bronze, etc.). The tip portion 28a comes into contact with the back surface 30b at a predetermined pressure (pressing force). The slider B 27 is slidable with a phase difference with respect to the slider A 25 along the back surface 30 b of the substrate 30 while maintaining this contact state.

  The substrate 30 has a long shape, and as shown in FIG. 2 and the like, both end portions thereof are fixed to attachment portions 14 b provided on the lower surface 14 a of the case 14.

  FIG. 5A is a top plan view of the surface 30a of the substrate 30, and is a pattern diagram of the conductive pattern A with which the contact A 26 contacts. FIG. 5B is a side view of the substrate 30. FIG. 5C is a lower plan view of the back surface 30b of the substrate 30 and is a pattern diagram of the conductive pattern B with which the contact B 28 comes into contact.

  The substrate 30 has a conductive pattern formed on the surface of a glass epoxy substrate or the like. Conductive patterns 301, 302, and 303 as shown in FIG. 5A are formed on the front surface 30a of the substrate 30, and conductive patterns 310 and 311 as shown in FIG. 5C are formed on the back surface 30b. ing.

  As shown in FIG. 2 and the like, the substrate 30 includes a battery 320 as a power supply unit and a communication control circuit 330 that communicates the detection result of the buckle switch 2.

  FIG. 6 is a block diagram of the buckle switch. The conductive patterns 310 and 303 are connected through holes and connected to the circuit power supply terminal V of the communication control circuit 330. The conductive patterns 301 and 302 are respectively connected to a communication control circuit, and a switch signal S1 based on the slide movement of the slider A 25 and a switch signal S2 based on the slide movement of the slider B 27 are input to the communication control circuit.

  Various types of batteries can be used as the battery 320. For example, a primary battery such as a nickel manganese battery, a secondary battery such as a lithium ion battery, and other chemical batteries can be used.

  As shown in FIG. 6, one end (for example, a positive terminal) of the battery 320 is connected to the conductive pattern 311 and the other end (for example, a negative terminal) is connected to a ground or a common terminal.

  The communication control circuit 330 includes a transmission unit 331 that performs signal processing based on the signals S1 and S2 input from the buckle switch 2 and transmits a signal S3 based on the buckle switch operation to the vehicle side.

  The communication control circuit 330 is supplied with power necessary for circuit operation from the battery 320. As shown in FIG. 6, the conductive patterns 303 and 310 and the circuit power supply terminal V are connected, and the GND (common) terminal and the circuit ground terminal G are connected.

  Only when the contact B 28 is in contact with the conductive patterns 311 and 310, power is supplied from the battery 320 to the communication control circuit 330 via the conductive patterns 311 and 310, so that the communication control circuit 330 can operate. Become. On the other hand, when the contact B 28 is not in contact with the conductive patterns 311 and 310, power is not supplied from the battery 320 to the communication control circuit 330, and the communication control circuit 330 is in an inoperable state.

(Buckle device operation)
The operation of the buckle device and the buckle switch will be described with reference to FIG. 1, FIG. 2, and FIG. 2 is a cross-sectional view of the buckle device before the tongue plate is inserted into the buckle body, and FIG. 7 is a cross-sectional view of the buckle device with the tongue plate inserted into the buckle body.

  The buckle device 1 includes a case 14 that constitutes the device body. The case 14 is a box-shaped cylindrical member that is open at both ends in the longitudinal direction, the opening at one end in the longitudinal direction is an anchor insertion port 16, and the opening at the other end in the longitudinal direction is a tongue insertion port 18. Yes. A base 20 that constitutes the main body of the apparatus together with the case is housed inside the case 14.

  As shown in FIGS. 1 and 2, the base 20 includes a flat bottom plate 22 that is elongated along the longitudinal direction of the case 14. A substantially plate-like anchor plate 24 as an anchor member is superposed on one end side in the longitudinal direction of the bottom plate 22, and the bottom plate 22 and the anchor plate 24 are mechanically connected by a rivet (not shown). The other end of the anchor plate 24 is fixed to the vehicle body (not shown) at the side of the vehicle seat, and the buckle device 1 is attached to the vehicle.

  On the other hand, side walls 33 are erected from both ends in the width direction of the bottom plate 22 in the thickness direction of the bottom plate 22, and ejectors 34 as moving bodies are disposed between the side walls 33. A part of the ejector 34 is engaged with a guide hole 36 formed in the bottom plate 22, and can slide within a predetermined range along the guide hole 36 in the longitudinal direction of the bottom plate 22. The ejector 34 is urged from the housing 201 side to the other end in the longitudinal direction of the bottom plate 22 via an ejector spring 206.

  The ejector 34 is connected to the slider A 25 of the buckle switch 2 described above. As a result, the slider A 25 is slid in conjunction with the movement of the ejector 34, that is, the operation of inserting and ejecting the tongue plate 130, and the switch operation of the buckle switch is performed.

  Here, as shown in FIG. 1, a tongue plate 130 is inserted between the side walls 33 from the other end in the longitudinal direction of the bottom plate 22. The tongue plate 130 includes a base portion 132 formed of a metal plate material. The base portion 132 is formed with a slit hole 134 that is elongated along the opposing direction of the side wall 33 in a state where the tongue plate 130 is inserted between the side walls 33, and is an intermediate portion in the longitudinal direction of the long webbing belt 140. Is inserted.

  The webbing belt 140 has a base end engaged with a winding shaft of a webbing winding device (not shown), and a winding shaft such as a spiral coil spring for urging the winding shaft in the direction of winding the webbing belt 140. The storing urging force of the urging means acts on the webbing belt 140.

  Further, an insertion plate portion 136 is formed on the base portion 132. The width of the insertion plate portion 136 is smaller than the interval between the side walls 33, and the insertion plate portion 136 of the tongue plate 130 is actually inserted between the side walls 33 (see FIG. 7).

  A through hole 138 penetrating in the thickness direction is formed in the insertion plate portion 136. When the insertion plate portion 136 reaches a predetermined position on one end side in the longitudinal direction of the bottom plate 22 between the side walls 33, a latch described later is provided. 50 engagement pieces 58 can be penetrated, and the engagement pieces 58 penetrate through the through holes 138, whereby the extraction of the tongue plate 130 from the buckle device 1 is regulated.

  On the other hand, as shown in FIGS. 1, 2, and 7, the buckle device 1 includes a latch 50. The latch 50 includes a base 52. Although it depends on the posture of the latch 50, the base 52 is formed in a flat plate shape that is generally longitudinal in the opposing direction of the side walls 33 and in the thickness direction along the longitudinal direction of the bottom plate 22. Both end portions in the direction enter into support holes 54 as support portions formed on both side walls 33. The base 52 (that is, the latch 50) is supported so as to be rotatable by a predetermined angle with the longitudinal direction of the base 52 as an axial direction until it is interfered with the inner peripheral portion of the support hole 54.

  Further, a flat plate-like connecting portion 56 extends from one end in the width direction of the base portion 52 in the longitudinal direction toward one side in the width direction of the base portion 52, and further, the connecting portion on the opposite side to the base portion 52. An engaging piece 58 extends from 56 toward the bottom plate 22 side.

  The distal end portion 58a of the engagement piece 58 corresponds to the through hole 60 formed in the bottom plate 22, and when the latch 50 is displaced, the engagement piece 58 is changed to the through hole 60 as shown in FIG. I can get in.

  As shown in FIGS. 1, 2, and 7, the thickness of one side (opposite to the bottom plate 22) of the ejector 34 described above corresponding to the tip of the engagement piece 58 of the latch 50 is A mounting piece 62 is provided integrally. The urging force from the ejector spring 206 acts on the ejector 34.

  Opposite to the distal end of the engagement piece 58 along the thickness direction of the bottom plate 22 in a state where the ejector 34 is located at a position where an external force other than the urging force from the ejector spring 206 is not applied. The mounting piece 62 is provided to do so. As shown in FIG. 7, the placement piece 62 interferes with the distal end portion of the engagement piece 58 while facing the distal end portion of the engagement piece 58, and the engagement piece 58 moves in a direction approaching the bottom plate 22 ( That is, the movement of the latch 50) is restricted.

  Further, stoppers 64 are extended from both ends in the longitudinal direction of the base 52. The stopper 64 is formed so that the tip side is positioned on the slide locus of the ejector 34 against the urging force of the ejector spring 206, and when the ejector 34 slides a predetermined distance against the urging force of the ejector spring 206. The ejector 34 comes into contact with the stopper 64.

  Further, a lock member 70 is disposed on the opposite side of the base 20 from the bottom plate 22 via the connecting portion 56 of the latch 50. The lock member 70 includes a base 72. The base 72 has a substantially square bar shape that is formed in the longitudinal direction along the opposing direction of the side walls 33.

  Both end portions of the base portion 72 enter engagement holes 74 formed in the side walls 33. The engagement hole 74 is formed on the other end side in the longitudinal direction of the side wall 33 with respect to the through hole 60, and the base portion 72 is supported by the side wall 33 so as to be rotatable about its own longitudinal direction around the axis. A pair of substantially fan-shaped lock pieces 76 are formed on both ends in the longitudinal direction of the base 72. The lock piece 76 corresponds to a contact piece 78 extending from both ends in the width direction of the connecting portion 56 (latch 50), and the lock piece 76 is in contact with the contact piece 78.

  Further, a contact portion 80 is formed at the longitudinal intermediate portion of the base portion 72. The contact portion 80 contacts the engagement piece 58 in a state where the engagement piece 58 of the latch 50 is separated from the bottom plate 22.

  On the other hand, the buckle device 1 includes a release button 90 as release means. The release button 90 includes a pressing portion 92 for operation. The pressing portion 92 has a plate shape in which the pressing surface faces the other end in the longitudinal direction of the bottom plate 22, and is a longitudinal direction along the opposing direction of the side walls 33.

  Side walls 94 extend from the vicinity of both ends in the longitudinal direction of the pressing portion 92 toward one end in the longitudinal direction of the bottom plate 22. These side walls 94 are opposed to each other along the opposing direction of the side wall 33 described above, and the end opposite to the bottom plate 22 is connected by the top wall 96, and opens toward the bottom plate 22 as a whole. It is a concave shape.

  Arms 98 extend from the ends of the side walls 94 opposite to the pressing portions 92 so as to face each other along the opposing direction of the side walls 94. Engaging protrusions 100 are formed at the distal ends of both arms 98 toward the other arm 98 and enter the guide holes 102 formed in the side wall 33. The guide hole 102 is a long long hole along the longitudinal direction of the bottom plate 22. The engagement protrusion 100 can be displaced by a predetermined range along the longitudinal direction of the bottom plate 22 by the inner peripheral portion of the guide hole 102, and thereby the movement direction of the release button 90 is changed in the longitudinal direction of the bottom plate 22 by the guide hole 102. It is regulated.

  A stopper 110 is disposed between the pressing portion 92 and the lock member 70. The stopper 110 includes a plate-like base portion 112 that is formed in a longitudinal direction along the opposing direction of the side wall 94. A pair of concave engaging pieces 114 that are open toward the bottom plate 22 when viewed along the longitudinal direction of the base 112 are formed on both ends of the base 112 in the longitudinal direction. The stopper 110 is supported by the lock member 70 by engaging with the base 72 of the lock member 70 described above.

  Further, an interference portion 116 is formed in the vicinity of both engagement pieces 114 of the stopper 110 so as to be able to interfere with the engagement protrusion 100 of the release button 90 described above.

  A compression coil spring 118 is disposed between the stopper 110 and the pressing portion 92 of the release button 90, and one end of the compression coil spring 118 is in contact with the side opposite to the pressing surface of the pressing portion 92. On the other hand, the other end of the compression coil spring 118 is in contact with the base portion 112 of the stopper 110, thereby urging the stopper 110 in the direction of separating from the pressing portion 92.

  In the buckle device 1, when the insertion plate portion 136 of the tongue plate 130 is inserted from the tongue insertion port 18 of the case 14 in the tongue extraction state shown in FIG. 2, the distal end portion of the insertion plate portion 136 abuts the end portion of the ejector 34. Then, the ejector 34 is slid toward one end in the longitudinal direction of the bottom plate 22 against the urging force of the ejector spring 206.

  When the ejector 34 slides by a predetermined amount toward one end in the longitudinal direction of the bottom plate 22, the opposed state between the mounting piece 62 of the ejector 34 and the engaging piece 58 of the latch 50 is released, and the ejector 34 moves the stopper 64 of the latch 50. The latch 50 is rotated by pressing.

  As a result, the tip of the engagement piece 58 moves closer to the bottom plate 22. In this state, the through hole 138 of the insertion plate portion 136 and the through hole 60 formed in the bottom plate 22 overlap. Therefore, in this state, as shown in FIG. 4, the rotated engagement piece 58 passes through the through hole 138 of the insertion plate portion 136 and the through hole 60 of the bottom plate 22.

  Further, when the latch 50 is rotated, the contact state between the engagement piece 58 of the latch 50 and the contact portion 80 of the lock member 70 is released. Here, since the lock piece 76 receives the urging force of the compression coil spring 118 via the stopper 110, the lock member 70 is rotated by the urging force of the compression coil spring 118 so as to be interlocked with the rotation of the latch 50. The piece 76 comes into contact with the contact piece 78 of the latch 50. For this reason, the rotation of the latch 50 in the direction in which the engagement piece 58 is separated from the bottom plate 22 is restricted, and the tongue plate 130 is held in the buckle device 1 to be in the buckle mounted state.

(Buckle switch operation)
8A (a) to 8F (a) are plan views of the surface 30a showing a contact state between the conductive pattern A on the surface 30a of the substrate 30 and the contact A26. 8A (b) to 8F (b) are plan views of the back surface 30b showing a contact state between the conductive pattern B on the back surface 30b of the substrate 30 and the contact B 28. FIG.

  FIG. 9 is a characteristic diagram showing the slide movement characteristics of the slider A (contact A) and the slider B (contact B), that is, the relationship between the time t and the distance X. As shown in FIG. 2, the distance X is set to the initial position (X = 0) when the slider A (contact A) is not inserted into the buckle device.

  In the following, the operation until the tongue plate 130 is inserted into the buckle device and the tongue plate 130 is latched to complete the mounting is shown in FIGS. 8A (a), 8 (b) to 8F (a), (b), and FIG. 9 will be described. The operation of ejecting the tongue plate 130 from the buckle device is the reverse operation.

  FIG. 8A (a) is a top plan view of the surface 30a showing a contact state between the conductive pattern A and the contact A on the surface 30a of the substrate 30 at t = 0. FIG. 8A (b) is a bottom plan view of the back surface 30b showing a contact state between the conductive pattern B on the back surface 30b and the contact B at t = 0.

  The sliding movement state of the contact A 26 and the contact B 28 shown in FIGS. 8A (a) and (b) is a state before the tongue plate 130 is inserted into the buckle device (at the time of discharging). As shown in FIG. 9, X = 0 for both the contact A 26 and the contact B 28. At this time, the tip end portion 26 a of the contact A 26 and the surface 30 a of the substrate 30 are in contact with each other in the contact A contact region 401. Therefore, the conductive patterns 301 and 303 are electrically connected via the contact A26.

  On the other hand, the front end 28 a of the contact B 28 and the back surface 30 b of the substrate 30 are in contact with each other in the contact B contact region 402. However, since the conductive pattern 311 and the contact B 28 are not in contact, the conductive patterns 310 and 311 are not electrically connected. Therefore, as shown in FIG. 6, power is not supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330. The communication control circuit 330 is in a circuit inoperable state.

FIG. 8B (a) is an upper plan view of the surface 30a showing a contact state between the conductive pattern A and the contact A on the surface 30a of the substrate 30 at t = t ₁ . FIG. 8B (b) is a bottom plan view of the back surface 30b showing a contact state between the conductive pattern B on the back surface 30b and the contact B at t = t ₁ .

The slide movement state of the contact A 26 and the contact B 28 shown in FIGS. 8B and 8B is a state at t = t ₁ after the insertion of the tongue plate 130 into the buckle device is started. As shown in FIG. 9, the contact A 26 slides integrally with the tongue plate 130, that is, the ejector 34 and moves to the position of X = L _A1 , but the contact B 28 has a phase difference with respect to the contact A 26. It moves to the position of X = L _B1 with (phase delay). At this time, the tip end portion 26 a of the contact A 26 is in contact with the conductive patterns 301 and 303 in the contact A contact region 401. Therefore, the conductive patterns 301 and 303 are electrically connected via the contact A26. The tip 28 b of the contact B 28 is in contact with the conductive patterns 310 and 311 in the contact B contact region 402. Therefore, the conductive patterns 310 and 311 are electrically connected via the contact B 28.

  Since the conductive patterns 310 and 311 are conducted, power is supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330 as shown in FIG. As a result, the communication control circuit 330 becomes operable. Since the conductive patterns 301 and 303 are conductive, the signal S1 is input from the buckle switch 2 to the communication control circuit 330 as an ON (Hi) signal. On the other hand, the signal S2 is input to the communication control circuit 330 as an off (Lo) signal.

Figure 8C (a) is at t = _{t 2,} is a top plan view of the surface 30a that indicates the state of contact between the conductive pattern A and the contact A of the surface 30a of the substrate 30. Figure 8C (b) is, at t = _{t 2,} a bottom plan view of the back surface 30b indicating the state of contact between the conductive pattern B and the contact B of the back surface 30b.

The slide movement state of the contact A 26 and the contact B 28 shown in FIGS. 8C (a) and (b) is a state at t = t ₂ after the insertion of the tongue plate 130 into the buckle device is started. As shown in FIG. 9, the contact A 26 integrally slides with the tongue plate 130, that is, the ejector 34, and further slides to the position of X = L _A2 , but the contact B 28 is in contact with the contact A 26. It moves to the position of X = L _{B2 with} a phase difference (further phase delay). At this time, the tip end portion 26 a of the contact A 26 is in contact with the conductive patterns 302 and 303 in the contact A contact region 401. Therefore, the conductive patterns 302 and 303 are electrically connected via the contact A26. The tip 28 b of the contact B 28 is in contact with the conductive patterns 310 and 311 in the contact B contact region 402. Therefore, the conductive patterns 310 and 311 are electrically connected via the contact B 28.

  The communication control circuit 330 is in a circuit operable state, and the signal S1 is input to the communication control circuit 330 from the buckle switch 2 as an off (Lo) signal and the signal S2 is input as an on (Hi) signal.

Figure 8D (a) is at t = _{t 3,} is a top plan view of the surface 30a that indicates the state of contact between the conductive pattern A and the contact A of the surface 30a of the substrate 30. FIG. 8D (b) is a bottom plan view of the back surface 30b showing a contact state between the conductive pattern B on the back surface 30b and the contact B at t = t ₃ .

The slide movement state of the contact A 26 and the contact B 28 shown in FIGS. 8D (a) and (b) is a state at t = t ₃ after the insertion of the tongue plate 130 into the buckle device is started. As shown in FIG. 9, the contact A 26 is integrally slid with the tongue plate 130, that is, the ejector 34, and further moved to the position of X = L to reach the position where the tongue plate 130 is completely inserted into the buckle device. To reach. On the other hand, the contact B 28 has a phase difference (further phase lag) with respect to the contact A 26 and moves to the position of X = L _B3 . At this time, the tip end portion 26 a of the contact A 26 is in contact with the conductive patterns 302 and 303 in the contact A contact region 401. Therefore, the conductive patterns 302 and 303 are electrically connected via the contact A26. The tip 28 b of the contact B 28 is in contact with the conductive patterns 310 and 311 in the contact B contact region 402. Therefore, the conductive patterns 310 and 311 are electrically connected via the contact B 28.

  The communication control circuit 330 is in a circuit operable state, and the signal S1 is input to the communication control circuit 330 from the buckle switch 2 as an off (Lo) signal and the signal S2 is input as an on (Hi) signal.

Figure 8E (a) is at t = _{t 4,} is a top plan view of the surface 30a that indicates the state of contact between the conductive pattern A and the contact A of the surface 30a of the substrate 30. Figure 8E (b) is, at t = _{t 4,} a bottom plan view of the back surface 30b indicating the state of contact between the conductive pattern B and the contact B of the back surface 30b.

The sliding movement state of the contact A 26 and the contact B 28 shown in FIGS. 8E (a) and (b) is a state at t = t ₄ after the insertion of the tongue plate 130 into the buckle device is started. As shown in FIG. 9, the contact A 26 has already moved to the position where the insertion into the buckle device is completed. On the other hand, the contact B 28 has a phase difference (further phase delay) with respect to the contact A 26 and moves to the position of X = L _B4 . At this time, the tip end portion 26 a of the contact A 26 is in contact with the conductive patterns 302 and 303 in the contact A contact region 401. Therefore, the conductive patterns 302 and 303 are electrically connected via the contact A26. The tip 28 b of the contact B 28 is in contact with the conductive patterns 310 and 311 in the contact B contact region 402. Therefore, the conductive patterns 310 and 311 are electrically connected via the contact B 28.

  The communication control circuit 330 is in a circuit operable state, and the signal S1 is input to the communication control circuit 330 from the buckle switch 2 as an off (Lo) signal and the signal S2 is input as an on (Hi) signal.

Figure 8F (a) is at t = _{t 5,} it is a top plan view of the surface 30a that indicates the state of contact between the conductive pattern A and the contact A of the surface 30a of the substrate 30. Figure 8F (b) is, at t = _{t 5,} a bottom plan view of the back surface 30b indicating the state of contact between the conductive pattern B and the contact B of the back surface 30b.

The slide movement state of the contact A 26 and the contact B 28 shown in FIGS. 8F (a) and (b) is a state at t = t ₅ after the insertion of the tongue plate 130 into the buckle device is started. As shown in FIG. 9, the contact A 26 has already moved to the position where the insertion into the buckle device is completed. On the other hand, the contact B 28 recovers the phase difference (phase lag) from the contact A 26 and moves to the position of X = L.

  The contact B 28 has a tip 28 a in contact with the contact B contact region 402 on the back surface 30 b of the substrate 30. However, since the conductive pattern 311 and the contact B 28 are not in contact, the conductive patterns 311 and 311 are not electrically connected. Therefore, as shown in FIG. 6, power is not supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330. The communication control circuit 330 becomes inoperable.

In the operation described above, power is supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330 during the period from t = t ₁ to t ₄ . As can be seen from FIG. 9, the period from t = t ₁ to t ₄ in which the slider B 27 moves the distance L is temporally longer than the period from t = t ₁ to t _{3 in which} the slider A 25 moves from the distance L. long. Therefore, the circuit operable state (on time) of the communication control circuit 330 can be lengthened, and a sufficient on time of the state detection operation can be secured.

During the on-time (t = t ₁ to t ₄ ) of the state detection operation described above, the switch signals S 1 and S 2 based on the slide movement of the slider A 25 and the slider B 27 are input to the communication control circuit 330. The By detecting that the switch signal S2 shifts from the ON state to the ON state, it is possible to detect that the tongue plate 130 has been inserted into the buckle body and latched. Based on the detection result, a detection signal S3 (latch detection signal) is transmitted from the transmission unit 331 to the reception unit on the vehicle side.

  Conversely, when the buckle device and the buckle switch operate in the reverse order described above, it can be detected that the tongue plate 130 has been discharged from the buckle body. Based on the detection result, a detection signal S3 (release detection signal) is transmitted from the transmission unit 331 toward the reception unit on the vehicle side.

During the time other than the on-time of the state detection operation (period from t = t ₁ to t ₄ ), that is, the standby time before the tongue plate 130 is inserted or after the insertion is completed (latch completion), the battery 320 to the communication control circuit 330 No power is supplied to the circuit power supply terminal V. Therefore, the power supply from the battery 320 to the communication control circuit 330 during this standby time can be made zero, and battery consumption can be greatly suppressed.

(Effects of the first embodiment)
The buckle switch 2 according to the first embodiment includes a substrate 30 having a conductive pattern formed on the surface and fixed to the housing 201, and a contact A 26 that contacts the surface of the substrate 30 while moving relative to the substrate 30. And a contact B 28 that is connected to the slider A 25 by a coil spring 29 and that moves relative to the slider A 25 while contacting the surface of the substrate 30 with a phase difference with respect to the slider A 25 by a switch operation. And a slider B27.

  As a result, the slider B 27 moves with a delay from the sliding movement of the slider A 25, and the state (ON time) in which the communication control circuit 330 can operate can be lengthened by this phase difference, and the ON time of the state detection operation Can be secured sufficiently.

  Further, power is supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330 only during the ON time of the state detection operation, and power is supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330 during other standby times. Not supplied. Thereby, the consumption of the battery 320 can be significantly suppressed. Therefore, in a state detection device provided with an independent power supply means (battery), a state detection device having a switch structure suitable for ensuring an on-time of a state detection operation, and a buckle device using the state detection device are provided. Can do.

  Moreover, since the buckle device according to the present embodiment includes independent power supply means (battery) in the buckle device, the buckle device has a high degree of freedom in design layout and uses the buckle device. This has the effect of restricting the movement of the case.

(Second embodiment of the present invention)
FIG. 10 is a cross-sectional view of the buckle switch according to the second embodiment along the slide movement direction. In the first embodiment, a conductive pattern is formed on both surfaces (the front surface 30a and the back surface 30b) of the substrate 30, and the contact A and the contact B slide while moving in contact with the front surface 30a and the back surface 30b of the substrate 30, respectively. However, in the second embodiment, the conductive pattern C is formed only on the surface 30 a of the substrate 30.

  As shown in FIG. 10, the slider A 25 as the first slider has a block shape formed by a slider A main body 25a and a protruding portion 25b provided to protrude upward. One end of a coil spring 29 as an elastic member is fixed to one end of the slider A main body 25a in the sliding direction, and another coil spring 29 is fixed to the other end of the slider A main body 25a. The lower surface 25c of the slider A main body 25a is attached with a contact A26 as a first contact that contacts the conductive pattern C formed on the surface 30a of the substrate 30, and the substrate 30 while the contact A26 contacts the surface 30a. It can be slid along the surface 30a.

  The protrusion 25 b of the slider A 25 is fitted into a fitting hole 34 b formed in the protrusion 34 a of the ejector 34 and moves integrally with the ejector 34. That is, it moves integrally with the ejector 34 in conjunction with operations such as insertion and ejection of the tongue plate 130.

  Further, as shown in FIG. 10, the slider C 31 as the second slider is connected to the slider A 25 by coil springs 29 and 29, and is operated by a switch operation (operation of inserting and ejecting the tongue plate 130). Relative to the substrate 30 while contacting the substrate 30.

  As shown in FIG. 10, the slider C 31 has a block shape formed by projecting portions 31 b and 31 c provided so as to project upward in order to fix the respective ends of the slider C main body 31 a and the coil springs 29 and 29. It is said that.

  A contact C32, which is a second contact in contact with the conductive pattern C formed on the surface 30a, is attached to a surface 31d where the slider C31 faces the surface 30a of the substrate 30.

  Similarly to the contact A 26, the contact C 32 is a metal (conductive) leaf spring, and is formed of a spring material (spring steel, spring stainless steel, spring phosphor bronze, etc.) having spring properties. The front end portion 32a comes into contact with the surface 30a at a predetermined pressure (pressing force). The slider C 31 is slidable with a phase difference with respect to the slider A 25 along the surface 30 a of the substrate 30 while maintaining this contact state.

  FIG. 11 is a top plan view of the surface 30a of the substrate 30 and is a pattern diagram of the conductive pattern C that contacts the contacts A and C as the first and second contacts.

  The conductive pattern 321 corresponds to the conductive pattern 301 in the first embodiment. The conductive pattern 322 corresponds to the conductive pattern 302 in the first embodiment. The conductive pattern 323 corresponds to the conductive pattern 311 in the first embodiment. The conductive pattern 324 corresponds to the conductive patterns 303 and 310 in the first embodiment.

  The other configuration is the same as that of the first embodiment, and a duplicate description is omitted.

  FIG. 12A is a top plan view of the surface 30a showing the contact state between the conductive pattern C and the contacts A and C on the surface 30a of the substrate 30 before the tongue plate is inserted (when discharged). FIG. 12B is an upper plan view of 30a showing a contact state between the conductive pattern C on the surface 30a of the substrate 30 and the contacts A and C during the insertion of the tongue plate. FIG. 12C is a top plan view of the surface 30a showing a contact state between the conductive pattern C of the surface 30a of the substrate 30 and the contacts A and C when the tongue plate is completely inserted (during holding).

  The slide movement state of the contact A 26 and the contact C 32 shown in FIG. 12A is the same as the buckle device of the tongue plate 130 in the state shown in FIGS. 8A and 8B of the first embodiment. This is a state corresponding to t = 0 at the start of insertion. At this time, the tip end portion 26 a of the contact A 26 and the surface 30 a of the substrate 30 are in contact with each other in the contact A contact region 401. Therefore, the conductive patterns 321 and 324 are electrically connected via the contact A 26.

  On the other hand, the tip 32 a of the contact C 32 and the surface 30 a of the substrate 30 are in contact with each other in the contact C contact region 403. However, since the conductive pattern 323 and the contact C 32 are not in contact, the conductive patterns 323 and 324 are not electrically connected. Therefore, as shown in FIG. 6, power is not supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330. The communication control circuit 330 is in a circuit inoperable state.

The slide movement state of the contact A 26 and the contact C 32 shown in FIG. 12B is the same as the buckle device of the tongue plate 130 in the state shown in FIGS. 8C and 8B of the first embodiment. Is the state corresponding to t = t ₂ . The contact C 32 moves with a phase difference (phase lag) with respect to the contact A 26.

  Since the conductive pattern 323 and the contact C 32 are in contact, the conductive patterns 323 and 324 are electrically connected. Therefore, as shown in FIG. 6, power is supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330. The communication control circuit 330 is in a circuit operable state.

  The communication control circuit 330 is in a circuit operable state, and the signal S1 is input from the buckle switch 2 to the communication control circuit 330 as an off (Lo) signal and the signal S2 is input as an on (Hi) signal.

The slide movement state of the contact A 26 and the contact C 32 shown in FIG. 12C is the same as the buckle device of the tongue plate 130 similar to the state shown in FIGS. 8F and 8B of the first embodiment. after insertion start is a state corresponding to t = t _5. The contact A 26 has already moved to the position where the insertion into the buckle device is completed. On the other hand, the contact C 32 also recovers the phase difference (phase lag) from the contact A 26 and moves to the position of X = L.

  The contact C 32 is in contact with the tip 32 a of the contact C contact region 403 on the surface 30 a of the substrate 30. However, since the conductive pattern 323 and the contact C 32 are not in contact, the conductive patterns 323 and 324 are not electrically connected. Therefore, as shown in FIG. 6, power is not supplied from the battery 320 to the circuit power supply terminal V of the communication control circuit 330. The communication control circuit 330 becomes inoperable.

  Also in the second embodiment described above, since the contact C 32 moves with a phase difference (phase lag) with respect to the contact A 26, the slider C 31 is the same as in the first embodiment. The time required for moving the distance L is longer than the time required for the slider A 25 to move the distance L. Therefore, the circuit operable state (on time) of the communication control circuit 330 can be lengthened, and a sufficient on time of the state detection operation can be secured.

(Effect of the second embodiment)
The buckle switch 2 according to the second embodiment has the following effects in addition to the effects of the first embodiment. That is, the conductive pattern C is formed only on one side of the substrate 30. Therefore, the formation cost of the conductive pattern on the substrate is reduced. Further, since the slider A 25 and the slider C 31 are brought into contact with the substrate 30 from the same direction, there is an effect that the assembling property is improved.

DESCRIPTION OF SYMBOLS 1 ... Buckle device, 2 ... Buckle switch, 14 ... Case, 16 ... Anchor insertion port, 18 ... Tongue insertion port, 20 ... Base, 22 ... Bottom plate, 24 ... Anchor plate, 25 ... Slider A, 26 ... Contact A, 27 ... Slider B, 28 ... Contact B, 29 ... Coil spring, 30 ... Substrate, 31 ... Slider C, 32 ... Contact C, 33 ... Side wall, 34 ... Ejector, 34a ... Pressing projection, 36 ... Guide hole, 50 ... Latch, 52 ... Base part, 54 ... Support hole, 56 ... Connection part, 58 ... Engagement piece, 58a ... Tip part, 60 ... Through hole, 62 ... Mounting piece, 64 ... Stopper, 70 ... Lock member, 72 ... Base part, 74 ... engaging hole, 76 ... lock piece, 78 ... contact piece, 80 ... contact part, 90 ... release button, 92 ... pressing part, 94 ... side wall, 96 ... upper wall, 98 ... arm, 100 ... engagement protrusion 102 ... Ga 110 ... stopper, 112 ... base, 114 ... engagement piece, 116 ... interference part, 118 ... compression coil spring, 130 ... tongue plate, 132 ... base, 134 ... slit hole, 136 ... insertion plate part, 138 ... Through hole, 140 ... webbing belt, 206 ... ejector spring, 301, 302, 303, 310, 311 ... conductive pattern, 320 ... battery, 321, 322, 323, 324 ... conductive pattern, 330 ... communication control circuit, 331 ... Transmission unit 401 ... Contact A contact area 402 ... Contact B contact area 403 ... Contact C contact area

Claims (8)

A substrate having a conductive pattern formed on the surface;
A first slider that is driven by a switch operation and includes a first contact that contacts the surface of the substrate while moving relative to the substrate;
A second contact which is connected to the first slider by an elastic member and has a second contact which moves relative to the first slider while contacting the surface of the substrate with a phase difference with respect to the first slider by the switch operation; A slider, and
A state detection device for detecting a state of the switch operation based on a conduction state between the first and second contacts and the conductive pattern.   2. The substrate according to claim 1, wherein the substrate has the conductive pattern on a front surface and a back surface, the first contact is in contact with the front surface, and the second contact is in contact with the back surface. State detection device.   The state detection apparatus according to claim 1, wherein the substrate has the conductive pattern on one side, and the first contact and the second contact are in contact with the one side.   The state detection device according to claim 1, wherein the elastic member is a coil spring. A state detection device according to any one of claims 1 to 4,
A communication control circuit for communicating a detection result of the state detection device;
And a power supply means for supplying power to the state detection device and the communication control circuit. An apparatus main body capable of inserting, holding, and discharging a tongue plate provided on a webbing of a vehicle seat belt apparatus;
The state detection device according to claim 5 placed in the device main body,
A buckle device comprising: detecting the state of the tongue plate by the state detection device.   The buckle device according to claim 6, wherein the communication control circuit is supplied with power from the power supply means only when the tongue plate is inserted or ejected. The communication control circuit is supplied with power from the power supply means via the second contact,
8. The buckle device according to claim 6, wherein insertion, holding, and ejection of the tongue plate are detected by detecting a contact state between the first contact and the conductive pattern. 9.

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