JP6417223B2 - Handle device - Google Patents

Description

  The present invention relates to a handle device attached to various devices.

  2. Description of the Related Art Conventionally, electric devices such as a switchboard, a control panel, and a switch are operated with operating components by a handle device having a handle arranged outside. A conventional handle device 100 shown in FIG. 10 includes a handle 102 and a rotating shaft 104 fixed to the handle 102. A plate body 108 is attached in front of the panel 106 of the electric device, and the rotation shaft 104 passes through the openings 112 and 110 of the plate body 108 and the panel 106. The rotating shaft 104 is connected to an operation component housed in an electric device. In FIG. 10, the operation parts of the electric device are stored in the case 114. When the handle 102 is rotated, the rotary shaft 104 is rotated and the operation component is operated.

  In addition, an O-ring 116 is attached to the rotating shaft 104 to prevent moisture and dust from reaching the operation parts and protect the electric device.

  The handle 102 needs to be locked in order to prevent an abnormal power supply due to an erroneous operation of the operation component. For example, a method may be considered in which a lock mechanism is incorporated in the rotation shaft 104, the handle 102 is pulled, the rotation shaft 104 is moved in the axial direction, and the lock is released. However, since the rotating shaft 104 moves in the axial direction, the deterioration of the O-ring 116 is accelerated. When the O-ring 116 is deteriorated, the airtightness of the operation component is impaired, and there is a possibility that the operation component and consequently the electric device may be broken. Bearing parts for maintaining airtightness are required, and the configuration is complicated.

  A method is conceivable in which the handle 102 of the handle device 100 is removed and the handle 102 is attached to the rotary shaft 104 only when operating. However, it is troublesome to attach and detach the handle 102, and the operability is deteriorated. Although a method of locking by inserting a pin into the handle 102 is also conceivable, it is troublesome to insert and remove the pin, resulting in poor operability.

  In Patent Document 1 below, the handle is fixed with a padlock to prevent erroneous operation. However, in order to operate the handle, it is necessary to unlock and lock the padlock, and the operability is poor.

JP-A-9-153327

  An object of the present invention is to provide a handle device that can be easily operated while preventing malfunction and preventing malfunction.

  In the handle device of the present invention, the rotation shaft passes through the opening of the plate. A slide shaft is passed through the through hole of the rotation shaft, and the slide shaft is fixed to the handle. An elastic body is provided between the rotating shaft and the handle. The convex part of the handle enters the groove or slit of the plate. The convex portion moves through the groove or slit by sliding and rotating the handle in accordance with the groove or slit.

  The groove or slit has an arc portion and a straight portion. The handle is slid to move the convex portion along the straight line portion, and the handle is rotated to move the convex portion along the arc portion.

  A sealing member is provided on the rotating shaft, and the device located inward of the sealing member is sealed.

  When the handle device is applied to the electric device, the rotation shaft is connected to the operation part of the electric device.

  According to the present invention, since the convex portion of the handle is in the groove or slit of the plate body, it is necessary to slide the handle in a direction perpendicular to the rotation direction in addition to the rotation. Inserting a slide procedure into the handle operation can prevent erroneous operation. The sliding of the handle does not deteriorate the operability as in the conventional case, and an erroneous operation can be prevented with a simple operation.

  By providing the seal member, it is difficult for moisture and dust to reach the inner device from the seal member, and failure of the device can be prevented. Since there is no need to pull the rotating shaft as in the prior art, the deterioration speed of the seal member can be reduced.

It is a figure which shows the external appearance of the handle apparatus of this invention. It is sectional drawing of the handle apparatus of this invention. It is a figure which shows the example of the cam switch connected to the rotating shaft, (a) is a figure in which a recessed part exists in a 90 degree position, (b) is a figure in which a recessed part exists in a 180 degree position. It is a figure which shows a mode that a convex part is guided along a groove part. It is a figure which shows the external appearance of the other handle apparatus of this invention. It is sectional drawing of the handle apparatus of FIG. It is sectional drawing of the handle apparatus which provided the board separately in front of the box. It is sectional drawing of the handle apparatus which provided the slit in the plate body. It is sectional drawing of the handle apparatus which used the case which accommodates an operation component as a plate. It is sectional drawing of the conventional handle apparatus.

  The handle device of the present invention will be described with reference to the drawings. The description will be given with an example of a handle device applied to an electrical device such as a switchboard, a control panel or a switch.

  The handle device 10 shown in FIGS. 1 and 2 is passed through an opening 14 formed in a plate body 12, a rotating shaft 16 passed through the opening 14, a through hole 18 formed in the rotating shaft 16, and a through hole 18. A slide shaft 20, a handle 22 to which the slide shaft 20 is fixed, an elastic body 24 between the rotary shaft 16 and the handle 22, a convex portion 26 provided on the handle 22, and a groove portion 28 in which the convex portion 26 is guided.

  In this embodiment, the front surface of the box of the electric device is a plate 12. Reference numeral 12 f is the front surface of the plate body 12, and reference numeral 12 b is the back surface of the plate body 12. An operation description or the like may be written on the surface 12f. The back surface 12b side is inside the box.

  The plate body 12, the rotation shaft 16, the slide shaft 20, the handle 22, and the like are made of a metal such as stainless steel, iron, or aluminum. Surface treatment for preventing rust and the like on the metal may be performed. Moreover, it can replace with a metal and can also use resin.

  The opening 14 is formed in the plate 12. The number and location of the openings 14 will vary depending on the configuration of the electrical device. A portion forming the opening 14 is a cylindrical body 30, and the rotating shaft 16 is passed through the opening 14. The cylindrical body 30 is not an essential configuration, and a seal member 32 (to be described later) may be disposed on the inner wall forming the opening 14 by using the thickness of the plate body 12.

  A seal member 32 is arranged around the rotary shaft 16, and the space between the inner wall of the cylindrical body 30 of the opening 14 and the rotary shaft 16 is closed by the seal member 32, so that moisture and dust do not enter inside the operation component and the electric device. Like that. Examples of the seal member 32 include O-rings, packing, and mechanical seals.

  In order to determine the position of the seal member 32, a concave portion 34 into which a part of the seal member 32 enters is provided in the rotary shaft 16. The shape of the recess 34 is not limited to a square, and may be changed as appropriate in accordance with the shape of the seal member 32. The recess 34 is not limited to the rotary shaft 16 but may be provided in the cylindrical body 30. In addition, as shown in FIG. 2, it is preferable to use a plurality of seal members 32 so that even if one seal member 32 is broken, the other seal members 32 can maintain airtightness.

  It is preferable to provide a bearing at an arbitrary position and to support the rotating shaft 16 with the bearing. The shake of the rotating shaft 16 can be suppressed. The structure is such that uneven wear of the seal member 32 can be prevented and moisture and dust can be appropriately prevented from entering.

  One end of the rotating shaft 16 protrudes outward from the plate body 12. The rotary shaft 16 has a through hole 18 formed in the vicinity of one end, and the slide shaft 20 is passed through the through hole 18. The slide shaft 20 is oriented at a right angle to the axial direction of the rotation shaft 16. The slide shaft 20 is not fixed with respect to the rotary shaft 16, and the handle 22 and the slide shaft 20 slide together with respect to the rotary shaft 16 by sliding the handle 22 in the axial direction of the slide shaft 20.

  The other end of the rotating shaft 16 is attached to an operation part of the electric device, and the position of the rotating shaft 16 is determined. As the rotary shaft 16 rotates, the operation component is operated.

  The rotary shaft 16 may be attached with a stopper such as an E-ring or a set collar to prevent the rotary shaft 16 from coming off. In addition, the rotary shaft 16 can have a cross section of the inner side of the plate body 12 wider than the opening 14 to prevent the rotary shaft 16 from coming off.

  A mechanism part (not shown) for positioning the operation parts of the electric device and the handle 22 may be housed in the case 35.

  As an operation part of the electric device, for example, a cam switch 36 shown in FIG. The cam switch 36 is opposed to the cam 38 fixed to the rotating shaft 16, the recess 40 formed on the outer periphery of the cam 38, the arm 44 that presses the cam 38, the movable terminal 46 attached to the arm 44, and the movable terminal 46. A fixed terminal 48 and a spring 50 attached to the movable terminal 46 are provided.

  The arm 44 is supported by an unillustrated guide or the like so as to be movable in the axial direction. One end 52 of the spring 50 is fixed to the movable terminal 46, and the position of the other end 54 is fixed to an arbitrary place so as not to move. The spring 50 applies a force to the movable terminal 46 in a certain direction of the cam 38, and the tip of the arm 44 presses the cam 38 via the movable terminal 46. Two concave portions 40 of the cam 38 are provided so that the direction of the concave portion 40 faces the direction of 90 ° with respect to the rotation shaft 16. When the tip of one arm 44 enters the recess 40, the tip of the other arm 44 exits from the recess 40.

  When the tip of the arm 44 enters the recess 40, the movable terminal 46 fixed to the arm 44 moves toward the fixed terminal 48 by the biasing force of the spring 50, and the movable terminal 46 and the fixed terminal 48 are connected. . When the tip of the arm 44 comes out of the recess 40, the movable terminal 46 fixed to the arm 44 moves in a direction away from the fixed terminal 48, and the connection between the movable terminal 46 and the fixed terminal 48 is cut. The operating component is operated depending on whether or not the movable terminal 46 and the fixed terminal 48 are connected.

  As shown in the cam switch 36 ′ in FIG. 3B, the concave portion 40 of the cam 38 may be opposed to the rotation shaft 16. The tips of both arms 44 enter or exit the recess 40 simultaneously. Both the movable terminal 46 and the fixed terminal 48 are connected or disconnected simultaneously. The cam switches 36 and 36 ′ used are appropriately changed depending on the circuit configuration of the electric device. The positions and number of the recesses 40 and the arms 44 can be changed as appropriate.

  The slide shaft 20 is fixed to the handle 22. A screw is used for the slide shaft 20, and a recess 56, a screw hole 58 and a through hole 60 are provided in the handle 22. One end of the rotary shaft 16 is inserted into the concave portion 56 of the handle 22, the slide shaft 20 is passed from the through hole 60 of the handle 22 through the concave portion 56 and the through hole 18 of the rotary shaft 16, and fastened to the screw hole 58. The shaft 20 is fixed to the handle 22. It is preferable to use a locking stopper so that the slide shaft 20 does not loosen. The length that the handle 22 can slide is determined by the size of the recess 56. The slide shaft 20 is not fixed to the rotary shaft 16, and the handle 22 can be slid with respect to the rotary shaft 16 in the axial direction of the slide shaft 20.

  When a gap is generated between the through hole 18 of the rotating shaft 16 and the slide shaft 20, the handle 22 rattles against the rotating shaft 16. Therefore, the gap between the through hole 18 and the slide shaft 20 is made as small as possible. It is preferable to reduce the friction between the through hole 18 and the slide shaft 20 by subjecting the through hole 18, the slide shaft 20, or both to a surface treatment that reduces the friction with a fluorine resin or the like.

  The slide shaft 20 is not limited to a screw, and a rivet may be used. Moreover, you may fix by welding or brazing using a linear rod member.

  The elastic body 24 is disposed between the rotary shaft 16 and the handle 22 in the recess 56 of the handle 22. The elastic body 24 applies a force in one direction between the rotating shaft 16 and the handle 22. An example of the elastic body 24 is a coil spring that allows the slide shaft 20 to pass through the coil spring. The major axis direction of the slide shaft 20 and the direction of the elastic force of the elastic body 24 coincide. Even if the handle 22 is slid, the handle 22 returns to the fixed position and is maintained. In FIG. 2, the elastic body 24 is a coil spring, but an air spring or a foamed material can also be used.

  2, even if the elastic body 24 is disposed between the screw head 62 of the slide shaft 20 and the rotary shaft 16, the slide shaft 20 is fixed to the handle 22, and the rotary shaft 16 and the handle 22 are The force of the elastic body 24 is applied between them.

  The convex portion 26 is provided at a portion of the handle 22 that faces the plate 12. A groove portion 28 shown in FIG. 4 is formed on the surface 12 f of the plate body 12, and the convex portion 26 enters the groove portion 28. Since the convex portion 26 is guided by the groove portion 28, the handle 22 needs to be moved according to the shape of the groove portion 28.

  The groove portion 28 includes an arc portion 64 that is a part of a circle centered on the rotation center of the rotating shaft 16 and a straight portion 66 that is connected to an end portion of the arc portion 64. There are two straight portions 66, and each straight portion 66 is perpendicular to the tangent of the circle. In the groove part 28, the position of one end of each linear part 66 is A and D, and the position of the other end is B and C. The other ends B and C of the linear portion 66 are connected to the end of the arc portion 64. When the convex part 26 exists in the linear part 66, the direction of the linear part 66 and the direction of the force of the elastic body 24 correspond.

  A and D are fixed positions of the handle 22, and when the convex portion 26 is at the position A or D, the position of the handle 22 is maintained by the force of the elastic body 24. By simply sliding the handle 22 and moving the convex portion 26 along the straight line portion 66, the rotating shaft 16 does not rotate, and the operation parts of the electric device are not operated. The convex portion 26 can move only along the straight portion 66, and the handle 22 cannot be rotated. An erroneous operation of the handle 22 can be prevented.

  After the convex portion 26 is moved to the position B or C, the convex portion 26 moves along the arc portion 64 by rotating the handle 22. When the convex portion 26 moves from B to C or from C to B, the operation component of the electric device is operated. As shown in FIG. 3, since the position of the recess 40 is in the direction of 90 degrees around the rotation axis 16, the angle at which the handle 22 is rotated is 90 degrees. As described above, the movable terminal 46 moves and is connected to or disconnected from the fixed terminal 48. The angle at which the handle 22 is rotated is appropriately changed depending on the structure of the operation part of the electric device, and the arc length of the arc portion 64 and the number of the straight portions 66 are also changed accordingly.

  After the convex portion 26 is moved to the position B or C, when the hand is released from the handle 22, the handle 22 is slid in the direction of the slide shaft 20 by the force of the elastic body 24, and the convex portion 26 is in the position A or D. Move to. The position of the handle 22 is maintained by the elastic body 24.

  It is preferable to open the space 68 so that the tip of the convex portion 26 does not touch the bottom of the groove portion 28. The handle 22 is easily slid and rotated. Further, the tip of the convex portion 26 is hemispherical, and is difficult to contact the side wall of the groove portion 28, so that the handle 22 can be easily slid and rotated. The tip of the convex portion 26 is not limited to a hemispherical shape, and may have a shape that tapers toward the tip by a C surface or an R surface. Moreover, if the convex part 26 enters into the groove part 28, it may become thicker as it goes to the tip.

  As described above, the operation parts of the electric device can be operated by sliding with the handle 22 and then rotating and releasing the hand. In addition to the rotation of the handle 22, a slide is also necessary, and erroneous operation can be prevented. There is no need to pull the rotating shaft 16 as in the prior art, and the deterioration of the seal member 32 can be delayed as compared with the prior art. Furthermore, there is no attachment / detachment of the handle 22 or the pin as in the prior art, the configuration is simplified, and the operation is also easy.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to said embodiment. For example, like the handle device 70 in FIGS. 5 and 6, the direction in which the handle 22 slides may be reversed as compared with the handle device 10 in FIGS. The handle device 70 has the same configuration except that the groove portion 28 is changed and the position of the elastic body 24 is changed so that the sliding direction of the handle 22 is reversed compared to the handle device 10. It is.

  Moreover, it is not limited to making the front surface of the box which accommodates an electric device into a plate. A plate body 84 may be separately attached to the front surface 82 of the box like the handle device 80 of FIG. The plate body 84 is fixed to the front surface 82 of the box body with screws, screws, an adhesive, or the like. The opening 86 in the front face 82 of the box may be larger than the opening 14 in the plate 84, and positioning when the handle device 80 is attached is facilitated.

  A seal member is attached to the rotary shaft 16, and the seal member 32 closes the space between the cylindrical 30 ′ forming the opening of the case 35 and the rotary shaft 16. Prevent moisture and dust from reaching the operating parts.

  If necessary, a plate packing may be sandwiched between the plate body 84 and the front surface 82 of the box to enhance the waterproof and dustproof performance. In FIG. 7, the seal member 32 is disposed at the position of the case 35, but the seal member 32 may be disposed at the position of the plate body 84.

  When the plate body 84 is separately disposed in front of the front surface 82 of the box body, the groove portion 28 of the plate body 12 can be changed to the slit 28 'as in the handle device 88 of FIG. The slit 28 ′ penetrates the plate body 12, and includes a straight line portion 66 and a curved line portion 64, similar to the groove portion 28, and guides the convex portion 26. It is also possible to keep the inside of the box airtight by closing one opening of the slit 28 'with the front face 82 of the box. In the present invention, the selection of the groove 28 and the slit 28 'is arbitrary depending on the design.

  As in the handle device 90 in FIG. 9, a front surface 92 of the case 35 that houses a mechanism unit or a switch attached to the rotating shaft 16 may be used as a plate.

  Although the front surface 92 of the case 35 is used as a plate body, a separate plate body may be disposed between the front surface 92 of the case 35 and the handle 22. Further, the groove device 28 or the slit 28 ′ is provided in an arbitrary plate body without using the case 35 or the like, and the convex portion 26 of the handle 22 is inserted therein, whereby the above-described handle devices 10, 70, 80, You may comprise the apparatus which show | plays the effect | action and effect similar to 88,90.

  Although the handle devices 10, 70, 80, 88, and 90 are applied to an electric device, the present invention is not limited to the electric device, and may be applied to a handle that opens and closes a door, for example. The plate body 12 is changed to a plate body constituting the door. The rotating shaft 16 is connected to a door locking mechanism, and the rotating shaft 16 rotates to operate locking and unlocking of the locking mechanism.

  In addition, the present invention can be carried out in a mode in which various improvements, modifications, and changes are added based on the knowledge of those skilled in the art without departing from the spirit of the present invention.

10, 70, 80, 88, 90: Handle device 12, 84: Plate body 12f: Plate body surface 12b: Plate body rear surface 14: Opening 16: Rotating shaft 18: Rotating shaft through hole 20: Slide shaft 22: Handle 24: Elastic body 26: Convex part 28: Groove part 28 ': Slit 30, 30': Cylindrical shape 32: Seal member 34: Concave part 35 of rotating shaft: Case 36, 36 ': Cam switch 38: Cam 40: Cam Recess 42: Roller 44: Arm 46: Movable terminal 48: Fixed terminal 50: Spring 52: Spring end 54: Spring other end 56: Handle recess 58: Screw hole 60: Handle through hole 62: Screw head 64: Arc portion 66: Linear portion 68: Space 82: Front face of box 86: Opening of box

Claims (4)

An opening provided in the plate,
A rotating shaft passed through the opening;
A through hole formed in the rotating shaft;
A slide shaft passed through the through hole;
A handle that covers an end of the rotating shaft and to which a slide shaft is fixed;
An elastic body exerting an elastic force between the rotating shaft and the handle;
A convex portion provided at a portion of the handle facing the plate,
A groove or a slit provided in the plate body, the convex portion being guided; and
Handle device with. The groove or slit is
An arc portion that is a part of a circle centered on the rotation axis;
A straight line portion that is oriented in a direction perpendicular to the tangent line of the circle and is connected to the arc portion;
The handle device according to claim 1, comprising: The handle device according to claim 1, wherein a seal member is provided on the rotating shaft. The handle device according to any one of claims 1 to 3, wherein the rotating shaft is connected to an operation component of an electric device.

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