JP5447151B2 - Connector lock mechanism and weighing scale - Google Patents

Description

  The present invention relates to a connector lock mechanism and a weighing scale including the same.

  For example, an operation unit is connected to a wheelchair scale disclosed in Non-Patent Document 1 via a cable. The cable is connected to the scale with a connector. An operation panel and a display panel are incorporated in the operation unit. In response to the operation of the operation panel, the scale begins to operate. For example, the weight value is displayed on the screen of the display panel.

TANITA Corporation, “TANITA Catalog 2009”, (Japan), TANITA Corporation, 2009, p84

  When the weight scale is transported to another place after use, a cable connecting the weight scale and the operation unit interferes with the transport work. Further, when trying to carry the weight scale while the cable is connected to the weight scale, the cable is often bent due to a change in the relative position between the weight scale and the operation unit. For this reason, there is a concern about disconnection of signal lines in the cable.

  Therefore, the present invention provides a connector lock mechanism that can easily remove a cable from a device and reduce the risk of disconnection of a signal line in the cable, and a weight scale including the connector lock mechanism.

  The connector lock mechanism according to the present invention includes a first connector connected to one end of a cable, a second connector provided in the device, to which the first connector is coupled, and the first connector is the A movable locking piece that locks the first connector when coupled to a second connector, and is disposed below the locking piece when the device is in use, with the locking piece facing the first connector And a pressing portion that causes the locking piece to lock to the first connector, and the pressing portion is pushed against an installation surface when the device is used, and raises the locking piece, When the device is separated from the installation surface, the lock piece is not pushed toward the first connector without being pressed against the installation surface, and the first link by the lock piece is not pushed. It causes the release of the lock of the compactors.

  In this connector lock mechanism, when the device is arranged on the installation surface for use, the pressing portion raises the lock piece by being pushed by the installation surface. When the first connector is coupled to the second connector and the locking piece is raised, the locking piece locks to the first connector. Since the locking piece locks the first connector, the connection between the first connector and the second connector is maintained. On the other hand, when the device is moved away from the installation surface, the pressing portion causes the lock piece to unlock the first connector. This makes it possible to disconnect the first connector from the second connector. Therefore, when the device is lifted from the installation surface, the lock is released and it is easy to disconnect the first connector and the second connector. When transporting the device, it is easy to remove the cable from the device, and the risk of disconnection of the signal line in the cable is reduced.

The connector locking mechanism may further include a first elastic body that biases the first connector in a direction in which the first connector is detached from the second connector.
In this configuration, when the lock to the first connector by the lock piece is released, the first connector is forcibly detached from the second connector by the first elastic body. Therefore, when the device is lifted from the installation surface, not only the lock is released, but also the first connector is forcibly detached from the second connector by the first elastic body. When the device is transported, the cable is automatically removed from the device, and the risk of disconnection of the signal line in the cable is further reduced.

The connector lock mechanism may further include a second elastic body that urges the pressing portion toward the installation surface.
In this configuration, when the device is separated from the installation surface, the pressing portion is forcibly moved toward the installation surface by the second elastic body. Therefore, the lock to the first connector by the lock piece is quickly released. When the device is transported, it is easier to remove the cable from the device, and the risk of disconnection of the signal line in the cable is further reduced.

A weight scale according to the present invention includes a base disposed on the installation surface, a platform on which a subject is placed, a load measuring device that is supported by the base and measures a load applied to the platform, A device having a connector locking mechanism, wherein the second connector of the connector locking mechanism is supported by the base and is electrically connected to the load measuring device.
When transporting the weighing scale, the cable can be easily detached from the weighing scale, and the risk of disconnection of the signal line in the cable is reduced.

It is a perspective view which shows the weight scale which concerns on embodiment of this invention, ie, a weight scale. It is a disassembled perspective view of the said weight scale. It is another disassembled perspective view of the said weight scale. It is a top view of the scale with the side cover removed. It is an expanded sectional view along the VV line of FIG. It is an expanded sectional view along the VI-VI line of FIG. It is an enlarged partial top view of the 1st side cover of the said weight scale, Comprising: It is a figure which shows a connector assembly. It is an expanded sectional view similar to FIG. 6 in the state where the said weight scale was lifted from the installation surface. FIG. 7 is an enlarged cross-sectional view similar to FIG. 6 in a state where a cable is to be connected to the connector assembly. It is a figure which shows the weight scale which concerns on other embodiment of this invention, Comprising: It is an expanded sectional view similar to FIG. It is a figure which shows the weight scale which concerns on other embodiment of this invention, Comprising: It is an expanded sectional view similar to FIG. It is a perspective view which shows the weight scale which concerns on other embodiment of this invention, ie, a weight scale.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 shows a weight scale 1 according to an embodiment of the present invention. The weight scale 1 is arranged above the base 2 shown in FIGS. 2 and 3, the pair of first load cell units 27a and the pair of second load cell units 27b supported by the base 2, and the load cell units 27a and 27b. The platform 14 is supported by the platform 14, and the first side cover 15 and the second side cover 16 are supported by the platform 14.

  As shown in FIG. 2, the weight scale 1 includes a base 2. The base 2 includes a steel rectangular frame 3 and steel corner plates 4 fixed to the four corners of the frame 3. The rectangular frame 3 includes a pair of side walls 3a and 3b and a pair of connecting plates 3c and 3d for connecting them. The connecting plates 3c and 3d are longer than the side walls 3a and 3b and have a smaller thickness than the side walls 3a and 3b.

  Adjustable legs 6 are respectively attached to the four corners of the frame 3. The adjustable leg 6 has a screw to be screwed into the frame 3 and a pedestal in contact with the floor surface, and the distance between the pedestal and the frame 3 can be adjusted by the rotation of the screw.

Load cell units 27 a and 27 b (load measuring devices) are arranged at the four corners of the frame 3. The pair of first load cell units 27a constitutes a first load cell unit group. A pair of second load cell units 27b are disposed spaced apart from the first load cell unit 27a in the left-right direction. The two second load cell units 27b constitute a second load cell unit group. Although detailed illustration is omitted, each of the load cell units 27a and 27b includes a load cell and a load transmission member that transmits a load applied from a mounting plate 29 described later to the load cell. The load cell includes a strain generating body that deforms according to an applied load, and one or more strain gauges that are attached to the strain generating body and output an electrical signal in an amount corresponding to the deformation of the strain generating body.
The load cell units 27a and 27b are supported by the base 2. Specifically, each of the load cell units 27 a and 27 b is attached to the corner plate 4.

  The base 2 is covered with a platform 14. The platform 14 is formed from, for example, a thin steel plate. The platform 14 includes a flat portion 14a disposed in parallel with the floor surface when the weight scale 1 is used, that is, when the weight is measured. A cutout 28 is formed in the flat portion 14a at a position corresponding to the position of the first load cell unit 27a and the second load cell unit 27b. A bent mounting plate 29 is disposed on the notch 28. The mounting plate 29 includes a flat upper wall and end walls before and after the upper wall. Both end walls before and after the mounting plate 29 are fixed to the flat portion 14a. The upper wall of the mounting plate 29 is above the flat portion 14 a of the platform 14 and extends in parallel to the flat portion 14 a of the platform 14.

  When the platform 14 is put on the base 2, each of the first load cell unit 27a and the second load cell unit 27b is disposed in the notch 28 of the platform 14, and the upper wall of each mounting plate 29 of the platform 14 is provided with the first load cell. The load transmitting member of the unit 27a or the second load cell unit 27b is covered and supported by the load cell unit 27a or 27b. Therefore, the load of the platform 14 and the load applied to the platform 14 are transmitted to the load cells of the load cell units 27a and 27b. The load cell units 27a and 27b measure the weight given to the platform 14, for example, the weight of the subject.

  On the flat portion 14a of the platform 14, a wheelchair on which the subject has boarded or a subject not on the wheelchair is placed. The scale 1 can measure the total weight of the subject and the wheelchair, and can also measure the weight of the subject who is not on the wheelchair. A portion of the platform 14 between the first load cell unit group and the second load cell unit group is a path 17 for the wheelchair.

  The platform 14 includes slopes 14b and 14c connected to the flat part 14a in addition to the flat part 14a. Each of the slopes 14b, 14c is formed so as to approach the floor surface as the distance from the flat portion 14a increases in the front-rear direction when the weight scale 1 is used. That is, the slopes 14b and 14c are formed so as to incline from the flat portion 14a to the floor surface when the weight scale 1 is used. In measuring the weight of the subject who has boarded the wheelchair, the subject goes up on the flat portion 14a while riding in the wheelchair. The function of the slopes 14b and 14c allows the wheelchair to move smoothly between the floor surface and the flat portion 14a. The traveling direction of the wheelchair corresponds to the “front-rear direction”.

  When the platform 14 is placed on the base 2, the flat portion 14 a is disposed in the space between the pair of side walls 3 a and 3 b of the frame 3 as shown in FIG. 3. Further, the connecting plates 3c and 3d of the frame 3 have a small thickness so that the slopes 14b and 14c of the platform 14 do not contact the connecting plates 3c and 3d. Accordingly, the load of the platform 14 is not transmitted directly to the base 2 but is transmitted to the base 2 via the load cell units 27a and 27b.

  As described above, in the weight scale 1, the flat portion 14 a of the platform 14 is disposed in the space between the pair of side walls 3 a and 3 b of the frame 3 of the base 2. In addition, load cell units 27a and 27b as load measuring devices are arranged inside a notch 28 formed in the flat portion 14a. Accordingly, the overall thickness of the scale 1 can be reduced. The load applied to the flat portion 14a of the platform 14 is transmitted to the load cell units 27a and 27b via the mounting plate 29.

  A first side cover 15 and a second side cover 16 made of a thin metal plate are mounted on the flat portion 14 a of the platform 14 and supported by the platform 14. The first side cover 15 covers a mounting plate 29 that covers the first load cell unit 27a. On the other hand, the second side cover 16 covers a mounting plate 29 that covers the second load cell unit 27b. The first side cover 15 and the second side cover 16 are spaced apart in the left-right direction. A wheelchair passage 17 is defined on the platform 14 between the first side cover 15 and the second side cover 16. In other words, the wheelchair passage 17 is a portion of the platform 14 that is not covered by the first side cover 15 and the second side cover 16.

  A handle 18 is fixed to one side cover, that is, the first side cover 15. Three wheels 19 are attached to the other side cover, that is, the second side cover 16. Each of the wheels 19 has a rotation axis orthogonal to the flat portion 14 a of the platform 14. The wheel 19 protrudes outside the outline of the scale 1. Applications of the handle 18 and the wheel 19 will be described later.

  As shown in FIG. 1, the weight scale 1 includes a connector assembly 24, and a cable 21 connected to the operation unit 13 can be detachably connected to the connector assembly 24. For example, an operation panel 22 and a display panel 23 are incorporated in the operation unit 13. The operation panel 22 has operation buttons (not shown) exposed on the surface of the operation unit 13. The display panel 23 has a screen (not shown) exposed on the surface of the operation unit 13. In response to the operation of the operation button, the weight scale 1 starts a weight measurement operation. A weight calculation device (not shown) is arranged inside the operation panel 22, and the weight calculation device calculates a weight value given to the platform 14 based on signals from the load cell units 27a and 27b. Perform the action. For example, a weight value is displayed on the screen of the display panel 23.

  An opening 25 is formed in the first side cover 15, and the cable 21 passes through the opening 25. The connector assembly 24 is exposed through the opening 25, and a person can disconnect and connect the cable 21 from the connector assembly 24 as necessary.

  When the weight scale 1 is not used, the person can raise the weight scale 1 in an upright posture by grasping the handle 18 with the cable 21 disconnected from the connector assembly 24 (not shown). The weight scale 1 in an upright posture is supported on the floor surface by wheels 19. The scale 19 can be smoothly transported on the floor surface by the wheels 19. During this transportation, the person carrying the scale 1 may grasp the handle 18.

  As shown in FIGS. 2 and 3, the connector assembly 24 is attached to and supported by a metal holder 32, for example. The connector assembly 24 is electrically connected to a circuit on the substrate 33, and the substrate 33 is also attached to and supported by the holder 32.

  The holder 32 is attached to the side wall 3 a of the frame 3 of the base 2 and supported by the base 2. As shown in FIG. 3, the holder 32 is attached to the frame 3 so that the holder 32 is positioned on the platform 14 when the platform 14 is put on the base 2. Since the holder 32 is attached to the frame 3, the load of the board 33 and the connector assembly 24 is supported by the frame 3 and not supported by the platform 14. Each of the load cell units 27a and 27b and the substrate 33 are connected by a cable 34. The board 33 together with the cables 34 is covered with the first side cover 15. Signals from the load cell units 27 a and 27 b are supplied from the cable 34 to the circuit on the substrate 33, and further supplied to the operation unit 13 through the connector assembly 24 and the cable 21.

  As shown in FIG. 4, four hook pieces 35 are formed on the edge of the first side cover 15 indicated by the phantom line, and the edge of the second side cover 16 similarly indicated by the imaginary line in FIG. In addition, four hook pieces 35 are formed. These hook pieces 35 are arranged substantially along the longitudinal direction of the side cover. The platform 14 has minute rectangular holes 36 corresponding to the individual hook pieces 35. Each hook piece 35 is inserted into a corresponding rectangular hole 36.

  In this way, as shown in FIG. 5, the platform 14 is hooked on the hook piece 35 of the first side cover 15. The platform 14 is also hooked on the hook piece 35 of the second side cover 16. The side covers 15 and 16 are positioned with respect to the platform 14 by the action of the hook pieces 35 and the rectangular holes 36.

  As shown in FIG. 4, the slope 14 b of the platform 14 is hung on one hook piece 35 of the four hook pieces 35 of the first side cover 15. The slope 14 b of the platform 14 is also hung on one hook piece 35 of the four hook pieces 35 of the second side cover 16. Accordingly, a part of the load of the slope 14b of the platform 14 is supported by the hook pieces 35 and the side covers 15 and 16 arranged on the left and right.

  Further, the slope 14 c of the platform 14 is hung on one hook piece 35 of the first side cover 15. The slope 14 c of the platform 14 is also hung on one hook piece 35 of the second side cover 16. Accordingly, a part of the load of the slope 14c of the platform 14 is supported by the hook pieces 35 and the side covers 15 and 16 arranged on the left and right.

  As shown in FIG. 5, a bracket 37 is fixed to the inner surface of the first side cover 15. The bracket 37 is in contact with the flat portion 14 a of the platform 14, and the load applied to the first side cover 15 is transmitted to the flat portion 14 a via the bracket 37. The bracket 37 is fixed to the flat portion 14a by a screw 38. In this way, the first side cover 15 is fixed to the platform 14.

  Although not shown, a similar bracket is also fixed to the inner surface of the second side cover 16, and the load applied to the second side cover 16 is transmitted to the flat portion 14a via the bracket. In addition, the second side cover 16 is fixed to the platform 14 by fixing the bracket to the flat portion 14 a with screws.

  In this scale 1, a connector assembly 24 and a substrate 33 that are electrical components electrically connected to the cable 21 are supported by a holder 32 that is an attachment member, and the holder 32 is supported by the base 2. For this reason, the load of the cable 21 is not transmitted to the platform 14. Therefore, even if the cable 21 sways, the load applied to the platform 14 is not affected, and accurate weight measurement is possible.

  As shown in FIG. 6, a gap d is secured between the holder 32 and the surface of the flat portion 14 a of the platform 14. The distance d is set to such a size that the contact between the platform 14 and the holder 32 is avoided even if the platform 14 is deformed.

  Since the connector assembly 24 and the board 33 are covered with the first side cover 15, the aesthetic appearance of the weight scale 1 is ensured. Although the first side cover 15 is supported by the platform 14, since the opening 25 through which the cable 21 passes is formed in the first side cover 15, the load of the cable 21 is not transmitted to the platform 14.

  As shown in FIGS. 6 and 7, the connector assembly 24 includes a flat plate 42, a connector case 43, and an anti-swing 45. The flat plate 42, the connector case 43, and the shaking stopper 45 are integrally formed of, for example, resin. The flat plate 42 of the connector assembly 24 is fixed to the holder 32.

  A first connector 44 at one end of the cable 21 is inserted into the connector case 43. As shown in FIG. 6, a second connector 46 mechanically and electrically connected to the first connector 44 is disposed inside the connector case 43. The second connector 46 is electrically connected to the circuit on the substrate 33. The first connector 44 and the second connector 46 may be of any type as long as they are mechanically and electrically connected to each other. For example, one of the connectors 44 and 46 may be a plug (male) and the other may be a socket (female).

  The anti-swing 45 of the connector assembly 24 is disposed at a position away from the connector case 43. The anti-sway 45 is annular, and the cable 21 is passed therethrough. When the first connector 44 is attached to the second connector 46, the anti-sway 45 defines the movement range of the cable 21. The anti-sway 45 is provided to ensure that the cable 21 passes through the opening 25 formed in the first side cover 15. The presence of the anti-swing 45 of the cable 21 ensures that the cable 21 extending from the first connector 44 passes through the opening 25 of the first side cover 15 with certainty. In other words, contact between the cable 21 and the first side cover 15 is reliably avoided. Therefore, the load of the cable 21 is not transmitted to the platform 14.

  A locking assembly 50 that locks the first connector 44 when the first connector 44 is coupled to the second connector 46 is provided below the connector assembly 24. The lock to the first connector 44 by the lock assembly 50 can be easily released.

  The lock assembly 50 includes a lock member 52 (lock piece), a pressing member 54 (pressing portion), a coil spring 56 (second elastic body), and a coil spring 58. The lock member 52 serves to lock the first connector 44. The pressing member 54 and the coil spring 58 serve as a lock assist mechanism that assists the lock of the lock member 52 to the first connector 44. The pressing member 54 and the coil spring 56 serve as a lock release mechanism that releases the lock of the lock member 52 to the first connector 44.

  The pressing member 54 is, for example, generally a cylinder, and its axis extends in a direction perpendicular to the flat portion 14 a of the platform 14. As shown in FIG. 6, when the weight scale 1 is used, that is, when the weight is measured, the flat portion 14a of the platform 14 is disposed in parallel with the floor surface FL (installation surface). That is, the weight scale 1 is arranged in a predetermined posture. At this time, the pressing member 54 is in a vertical state, and its lower end surface comes into contact with the floor surface FL. The pressing member 54 has two flanges 60 and 62.

  A cylindrical guide 64 is attached to the holder 32. The guide 64 has a bottom wall, and a through hole is formed in the bottom wall. The body portion other than the flanges 60 and 62 of the pressing member 54 passes through the through hole, and the through hole of the guide 64 allows the pressing member 54 to move in the axial direction. However, even when the weight scale 1 is lifted from the floor surface FL, the flange 60 above the pressing member 54 is caught by the bottom wall of the guide 64 so that the pressing member 54 does not fall off the weight scale 1.

  A coil spring 56 is disposed between the bottom wall of the guide 64 and the flange 62 below the pressing member 54. The coil spring 56 is disposed around the body portion of the pressing member 54. The coil spring 56 is compressed by the bottom wall of the guide 64 and the flange 62. Accordingly, the coil spring 56 always urges the flange 62 downward in the drawing, that is, toward the floor surface FL.

  A hole is formed in the upper end surface of the pressing member 54, and a coil spring 58 and a lock member 52 are disposed inside the hole. The coil spring 58 always urges the lock member 52 upward in the drawing, that is, toward the flat plate 42. A recess or a circumferential groove 47 is formed in the first connector 44, and the upper end of the lock member 52 can enter the circumferential groove 47. When the upper end of the locking member 52 enters the circumferential groove 47, the locking member 52 locks the first connector 44, and the connection between the first connector 44 and the second connector 46 is maintained.

  A coil spring 70 (first elastic body) is disposed around the second connector 46. The coil spring 70 serves as a connector detachment mechanism that assists in detaching the first connector 44 from the second connector 46. The coil spring 70 causes the first connector 44 to move in the direction in which the first connector 44 is detached from the second connector 46 when the first connector 44 is coupled to the second connector 46 (that is, leftward in the figure). Energize.

  With respect to this embodiment, the first connector 44, the connector assembly 24 (including the second connector 46 and the coil spring 70), and the lock assembly 50 (including the lock member 52, the pressing member 54, the coil spring 56, and the coil spring 58). Is called a connector locking mechanism in this specification.

  As shown in FIG. 6, when using the weight scale 1, that is, when measuring the weight, the weight scale 1 is arranged in a predetermined posture, and the lower end surface of the pressing member 54 contacts the floor surface FL. The pressing member 54 is pushed by the floor surface FL to push up the coil spring 58 together with the lock member 52. The pressing member 54 and the coil spring 58 function as a lock assist mechanism. That is, when the first connector 44 is coupled to the second connector 46, the pressing member 54 and the coil spring 58 press the lock member 52 toward the first connector 44. When the upper end of the lock member 52 enters the circumferential groove 47, the lock member 52 locks the first connector 44. Thereby, the coupling between the first connector 44 and the second connector 46 is maintained.

  Next, it is assumed that the scale 1 is transported from the place of use, that is, the place of weight measurement to the storage place. As shown in FIG. 8, when the weight scale 1 is lifted, the adjustable leg 6 of the weight scale 1 moves away from the floor surface FL. The lower end surface of the pressing member 54 of the lock assembly 50 is also separated from the floor surface FL. As a result, the pressing member 54 is not pressed against the floor surface FL and does not press the lock member 52 toward the first connector 44. Therefore, the pressing member 54 functions as a lock release mechanism, and causes the lock to the first connector 44 by the lock member 52. As a result, the coupling between the first connector 44 and the second connector 46 can be disconnected. Therefore, when the weight scale 1 is lifted from the floor surface FL, the lock is released and the first connector 44 and the second connector 46 can be easily disconnected. When carrying the scale 1, it is easy to remove the cable 21 from the device, and the risk of disconnection of a signal line (not shown) in the cable 21 is reduced.

  When the weight scale 1 is separated from the floor surface FL, the coil spring 56 that urges the pressing portion 54 toward the floor surface FL functions as a lock release mechanism, and the pressing portion 54 is forced toward the floor surface FL. Move. The pressing member 54 is propelled toward the floor surface FL by a coil spring 56 as well as gravity. Therefore, the lock to the first connector 44 by the lock member 52 is quickly released. When carrying the weight scale 1, the cable 21 can be further easily detached from the weight scale 1, and the risk of disconnection of the signal line in the cable 21 is further reduced. The downward movement of the pressing member 54 is restricted when the flange 60 hits the bottom wall of the guide 64, and the pressing member 54 does not fall off the scale 1.

  When the lock to the first connector 44 by the lock member 52 is released, the coil spring 70 functions as a connector detachment mechanism that assists the detachment of the first connector 44 from the second connector 46. That is, the coil spring 70 forcibly separates the first connector 44 from the second connector 46 by the leftward elastic force in the drawing. Therefore, when the weight scale 1 is lifted from the floor surface FL, not only the lock is released, but also the first connector 44 is forcibly detached from the second connector 46 by the coil spring 70. When carrying the weight scale 1, the cable 21 is automatically detached from the weight scale 1, and the risk of disconnection of the signal line in the cable 21 is further reduced.

  Thus, the cable 21 is disconnected from the scale 1 when the first connector 44 is detached from the second connector 46 of the connector assembly 24. The first connector 44 can be easily removed from the anti-sway 45.

  As described above, in the state where the cable 21 is disconnected from the weight scale 1, the weight scale 1 is raised to the upright posture when the weight scale 1 is transported. Although not shown, the weight scale 1 is supported on the floor surface FL by wheels 19 and can be easily moved on the floor surface FL by the wheels 19.

  Next, a scene where an operator tries to connect the cable 21 to the connector assembly 24 is assumed. As shown in FIG. 9, the weight scale 1 is arranged so that the flat portion 14 a of the platform 14 is parallel to the floor surface FL for use. At this time, the pressing member 54 rises while being pressed by the floor surface FL and compressing the coil spring 56. As the pressing member 54 rises, the lock member 52 also rises. The upper end of the lock member 52 reaches a position higher than the lower end of the first connector 44 that is to be coupled to the second connector 46.

  A slope 53 is formed on the upper portion of the lock member 52. The slope 53 is so low that it goes away from the second connector 46. That is, the slope 53 is lower as it is closer to the outlet of the connector case 43. The operator inserts the first connector 44 into the anti-sway 45 and further pushes it into the connector case 43. At this time, the tip of the first connector 44 abuts against the slope 53 of the lock member 52. When the first connector 44 is further propelled, the slope 53 is pushed against the tip of the first connector 44, and the lock member 52 descends against the elastic force of the coil spring 58.

  When the operator further pushes the first connector 44, the first connector 44 is coupled to the second connector 46 as shown in FIG. At this time, the coil spring 70 is compressed by the tip of the first connector 44. When the first connector 44 is coupled to the second connector 46, the lock member 52 locks the first connector 44 by the upper end of the lock member 52 entering the circumferential groove 47. Thereby, the coupling between the first connector 44 and the second connector 46 is maintained.

In this embodiment, instead of each of the coil springs 56, 58, 70, other types of springs may be provided, or other elastic bodies such as rubber members may be provided.
Moreover, although it is preferable to provide the coil springs 56 and 70, it is not essential, and one or both of them may be omitted. If there is no coil spring 56, the flange 62 may be omitted.
Furthermore, instead of the circumferential groove 47, a recess or notch having another shape into which the lock member 52 enters may be formed in the first connector 44.

  FIG. 10 shows another embodiment. In this embodiment, a lock assembly 80 is provided instead of the lock assembly 50. In FIG. 10, the same reference numerals are used to indicate the same components as those in the above-described embodiment, and these components will not be described in detail. The coil spring 56, the flange 62, and the coil spring 58 of the above embodiment are not provided in this embodiment.

  In the lock assembly 80, the pressing member 84 (pressing portion) is, for example, generally a cylinder like the pressing member 54 of the above-described embodiment, and its axis is in a direction perpendicular to the flat portion 14a of the platform 14. It extends. The pressing member 84 has a flange 60, and a lock piece 82 is integrated with the upper end of the pressing member 84. A coil spring 88 is attached to the lower end of the pressing member 84. When the weight scale 1 is used, the coil spring 88 is compressed by the lower end surface of the pressing member 84 and the floor surface FL, and applies an upward elastic force to the pressing member 84 and the lock piece 82. For this embodiment, a first connector 44, a connector assembly 24 (including a second connector 46 and a coil spring 70), and a lock assembly 80 (including a pressing member 84 and a coil spring 88) are referred to herein as connectors. This is called a lock mechanism.

  When the weight scale 1 is lifted from the state of FIG. 10, the adjustable leg 6 of the weight scale 1 moves away from the floor surface FL. The pressing member 84 of the lock assembly 80 does not press the lock piece 82 toward the first connector 44 without being pressed against the floor surface FL. The pressing member 84 falls toward the floor surface FL due to gravity. A frictional force is generated between the first connector 44 and the lock piece 82 by the elastic force of the coil spring 70, and this frictional force acts in the direction opposite to the gravity acting on the pressing member 84. However, the spring constant of the coil spring 70 and the amount of deformation thereof are designed so that this frictional force is smaller than the gravity acting on the pressing member 84. As a result, when the force by which the floor surface FL pushes up the pressing member 84 disappears, the gravity acting on the pressing member 84 overcomes this frictional force and the pressing member 84 falls toward the floor surface FL. Therefore, the pressing member 84 functions as a lock release mechanism, and causes the lock piece 82 to unlock the first connector 44. The downward movement of the pressing member 84 is restricted when the flange 60 abuts against the bottom wall of the guide 64, and the pressing member 84 does not fall off the scale 1.

  When the lock to the first connector 44 by the lock piece 82 is released, the coil spring 70 functions as a connector detachment mechanism that assists the detachment of the first connector 44 from the second connector 46. That is, the coil spring 70 forcibly separates the first connector 44 from the second connector 46 by the leftward elastic force in the drawing.

  Next, when an operator intends to connect the cable 21 to the connector assembly 24, the scale 1 is arranged so that the flat portion 14a of the platform 14 is parallel to the floor surface FL for use. At this time, the pressing member 84 is pushed upward by the floor surface FL. The operator inserts the first connector 44 into the anti-sway 45 and further pushes it into the connector case 43. At this time, the tip of the first connector 44 abuts against the slope 53 of the lock piece 82. When the first connector 44 is further propelled, the inclined surface 53 is pressed against the tip of the first connector 44, and the pressing member 84 including the lock piece 82 descends against the elastic force of the coil spring 88.

  When the operator further pushes the first connector 44, the first connector 44 is coupled to the second connector 46, as shown in FIG. At this time, the coil spring 70 is compressed by the tip of the first connector 44. When the first connector 44 is coupled to the second connector 46, the lock piece 82 locks the first connector 44 by the upper end of the lock piece 82 entering the circumferential groove 47. Thereby, the coupling between the first connector 44 and the second connector 46 is maintained.

In this embodiment, instead of each of the coil springs 70 and 88, another type of spring may be provided, or an elastic body other than the spring, for example, a rubber member may be provided.
Further, although it is preferable to provide the coil spring 70, it is not essential, and this may be omitted.
Furthermore, instead of the circumferential groove 47, a recess or notch having another shape into which the lock piece 82 enters may be formed in the first connector 44.

  FIG. 11 shows still another embodiment. In this embodiment, a lock assembly 150 is provided instead of the lock assembly 80. In addition, a first connector 144 having another shape is provided at one end of the cable 21 instead of the first connector 44. In FIG. 11, the same reference numerals are used to indicate the same components as those in the above-described embodiment, and these components will not be described in detail. The coil spring 56, the flange 62, and the coil spring 58 of the above embodiment are not provided in this embodiment.

  In the lock assembly 150, the pressing member 154 (pressing portion) is, for example, generally a cylinder like the pressing member 54 of the above-described embodiment, and its axis is in a direction perpendicular to the flat portion 14 a of the platform 14. It extends. The pressing member 154 has a flange 60, and a lock piece 152 is integrated with the upper end of the pressing member 154. A coil spring 88 is attached to the lower end of the pressing member 154. When the weight scale 1 is used, the coil spring 88 is compressed by the lower end surface of the pressing member 154 and the floor surface FL, and applies an upward elastic force to the pressing member 154 and the lock piece 152. For this embodiment, the first connector 144, the connector assembly 24 (including the second connector 46 and the coil spring 70), and the lock assembly 150 (including the pressing member 154 and the coil spring 88) are referred to herein as the connector. This is called a lock mechanism.

  The first connector 144 has a flange 147 instead of the circumferential groove 47. The peripheral surface of the flange 147 is a slope 148. The slope 148 has a larger diameter as the distance from the second connector 46 increases. That is, the slope 148 has a larger diameter as it is closer to the outlet of the connector case 43.

  When the weight scale 1 is lifted from the state of FIG. 11, the adjustable leg 6 of the weight scale 1 moves away from the floor surface FL. The pressing member 154 of the lock assembly 150 does not press the lock piece 152 toward the first connector 144 without being pressed against the floor surface FL. The pressing member 154 falls toward the floor surface FL due to gravity. A frictional force is generated between the flange 147 of the first connector 144 and the lock piece 152 by the elastic force of the coil spring 70, and this frictional force works in the direction opposite to the gravity acting on the pressing member 154. However, the spring constant of the coil spring 70 and the amount of deformation thereof are designed so that this frictional force is smaller than the gravity acting on the pressing member 154. As a result, when the floor surface FL has no force to push up the pressing member 154, the gravity acting on the pressing member 154 overcomes this frictional force and the pressing member 154 falls toward the floor surface FL. Therefore, the pressing member 154 functions as a lock release mechanism, and causes the lock piece 152 to release the lock on the first connector 144. The downward movement of the pressing member 154 is restricted when the flange 60 hits the bottom wall of the guide 64, and the pressing member 154 does not fall off the scale 1.

  When the lock to the first connector 144 by the lock piece 152 is released, the coil spring 70 functions as a connector detachment mechanism that assists the detachment of the first connector 144 from the second connector 46. That is, the coil spring 70 forcibly separates the first connector 144 from the second connector 46 by the leftward elastic force in the drawing.

  Next, when an operator intends to connect the cable 21 to the connector assembly 24, the scale 1 is arranged so that the flat portion 14a of the platform 14 is parallel to the floor surface FL for use. At this time, the pressing member 154 is pushed upward by the floor surface FL. The operator inserts the first connector 144 into the anti-sway 45 and further pushes it into the connector case 43. At this time, the flange 147 of the first connector 144 abuts against the lock piece 152. When the first connector 144 is further propelled, the flange 152 is pushed by the flange 147 of the first connector 144, and the pressing member 154 including the lock piece 152 descends against the elastic force of the coil spring 88.

  When the operator further pushes the first connector 144, the first connector 144 is coupled to the second connector 46, as shown in FIG. At this time, the coil spring 70 is compressed by the tip of the first connector 144. When the first connector 144 is coupled to the second connector 46, the upper end of the lock piece 152 enters the portion of the first connector 144b closer to the cable 21 than the flange 147, whereby the lock piece 152 is The connector 144 is locked. Thereby, the coupling between the first connector 144 and the second connector 46 is maintained.

In this embodiment, instead of each of the coil springs 70 and 88, another type of spring may be provided, or an elastic body other than the spring, for example, a rubber member may be provided.
Further, although it is preferable to provide the coil spring 70, it is not essential, and this may be omitted.
Further, instead of the flange 147, a convex portion or a protrusion having another shape on which the lock piece 152 is hooked may be formed on the first connector 144.

  In each of the embodiments described above, a handrail member 200 may be coupled to the second side cover 16 as shown in FIG. When the subject gets on the wheelchair and rests on the flat portion 14a of the platform 14, the subject can hold the handrail member 200. Even if the subject is a physically handicapped person with a symptom that the body trembles, the subject may be able to stop shaking the body by gripping the handrail member 200 in some cases. Suppressing body tremor stabilizes the measured weight value.

  A subject who is not on a wheelchair can also grab the handrail member 200. Even if the subject is a physically handicapped person having a trembling symptom, the subject may be able to reduce the tremor by gripping the handrail member 200. Suppressing body tremor stabilizes the measured weight value. Further, even when the subject has difficulty in legs, the subject can stand on the platform 14 by gripping the handrail member 200.

  As mentioned above, although the weight scale which concerns on embodiment was demonstrated, this invention is not limited to a weight scale, The weight scale which measures the weight of to-be-measured objects other than a test subject's body weight is included. Furthermore, the connector lock mechanism of each of the embodiments described above can be provided in another device other than the weigh scale.

DESCRIPTION OF SYMBOLS 1 Weight scale (weighing scale, apparatus) 2 Base, 13 Operation unit, 14 Platform, 27a, 27b Load cell unit (load measuring device), 21 Cable, 24 Connector assembly, 42 Flat plate, 44,144 1st connector, 45 Anti-sway, 46 Second connector, 50, 80, 150 Lock assembly, 52 Lock member (lock piece), 54, 84, 154 Press member (press part), 56 Coil spring (second elastic body), 70 Coil spring ( 1st elastic body), 82,152 Lock piece, FL floor surface (installation surface).

Claims (4)

A first connector connected to one end of the cable;
A second connector provided in the device to which the first connector is coupled;
A movable locking piece that locks the first connector when the first connector is coupled to the second connector;
A pressing portion that is disposed below the lock piece when the device is used, and that raises the lock piece toward the first connector to cause the lock piece to lock the first connector;
The pressing portion is pushed by an installation surface to raise the lock piece when the device is used, and when the device is separated from the installation surface, the lock piece is not pushed by the installation surface and the first connector is pushed. A connector locking mechanism that causes the lock piece to be unlocked by the lock piece without being pressed toward the connector.   The connector lock mechanism according to claim 1, further comprising a first elastic body that biases the first connector in a direction in which the first connector is detached from the second connector.   The connector lock mechanism according to claim 1, further comprising a second elastic body that urges the pressing portion toward the installation surface. A base disposed on the installation surface;
A platform on which the subject is placed;
A load measuring instrument that is supported by the base and measures a load applied to the platform;
A connector locking mechanism according to any one of claims 1 to 3,
The weight scale as the device, wherein the second connector of the connector lock mechanism is supported by the base and is electrically connected to the load measuring device.

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