JP6395303B2 - Electric razor - Google Patents

Description

  The present invention relates to an electric razor including a tiltable shear blade unit, and in particular, a reaction force adjusting structure capable of switching the tilt reaction force when the shear blade unit tilts to a plurality of stages, and a shear blade unit The present invention relates to an electric razor having a lock structure that prevents forward and backward tilting.

  With regard to this type of electric razor, the present applicant has previously proposed an electric razor having a swing lock mechanism (Patent Document 1). There, a razor head is constituted by a power module and a shearing blade unit supported by a head frame of the power module so as to tilt forward and backward, and a swing lock mechanism is provided between the shearing blade unit and the head frame. The swing lock mechanism includes a lock knob assembled to the shear blade unit, a lock piece that slides up and down following the knob, and a lock engagement groove provided in the head frame. By engaging, the shear blade unit is prevented from tilting back and forth.

  In the electric shaver according to the present invention, the tilting reaction force of the shearing blade unit supported so as to be tiltable back and forth and / or right and left is adjusted by the reaction force adjusting structure. An electric shaver provided with this type of adjusting structure is disclosed in Patent Document 2. Can be seen. However, the adjustment structure in Patent Document 2 is intended for adjustment of the float characteristics (float amount and float force) of the blade head part that is float-supported so as to be vertically movable and horizontally tiltable. There, a U-shaped leaf spring is disposed between the main body grip portion and the blade head portion, and the lever shaft disposed on the lower surface of the leaf spring is rotated by a switch (lever) to be provided on the lever shaft. The float characteristic is changed by changing the contact position between the protrusion and the leaf spring. In addition, a compression coil type float spring is provided between the main body grip portion and the blade head portion in addition to the plate spring.

  The switch located on the side of the body grip can be switched between soft float, hard float, and float lock. In the soft float state, the blade head is only a predetermined amount against the urging force of the float spring. When pushed down, the projecting portion comes into contact with the leaf spring and pushes up and biases the blade head portion with the total biasing force of the float spring and the leaf spring. Further, in the hard float state, in the free state before the blade head part is pushed down, the projecting part comes into contact with the free end of the leaf spring and the blade head part is pushed down at the same time. The blade head is pushed up and biased by the total biasing force of the spring. In the float lock state, the locking projection comes into contact with the lower surface of the blade head portion to prevent the blade head portion from being pushed down.

Japanese Patent Laying-Open No. 2004-242769 (paragraph number 0040, FIG. 1) Japanese Patent No. 3937941 (Claim 1, FIGS. 9 to 12)

  According to the electric razor of Patent Document 1, the forward and backward tilting of the shearing blade unit can be locked or unlocked by sliding the lock knob up and down. Further, in the unlocked state, the tilting force of the shearing blade unit can be adjusted by the user himself / herself by holding both sides of the shearing blade unit with the thumb and the index finger. However, when adjusting the tilting force by the user himself / herself, it is necessary to continue to hold both sides of the shear blade unit with the thumb and index finger, which is troublesome, and it is difficult to hold the shear blade unit depending on the cutting site of the beard. .

  In that respect, according to the electric razor of Patent Document 2, it is possible to switch the float characteristic of the blade head portion between the soft float state and the hard float state and further switch the blade head portion to the float lock state by simply switching the switch. However, it is necessary to provide a pair of protrusions for leaf springs and protrusions for locking on the lever shaft, and to provide a compression coil type float spring separately from the leaf springs, so an adjustment structure for changing the float characteristics It is inevitable that the cost becomes complicated and the cost increases. In the float lock state, the lower surface of the blade head portion is only received by the locking projection, and therefore the float lock state cannot be maintained in a stable state. For example, when an external force in the front-rear direction or the left-right direction acts on the blade head portion, the blade head portion tends to tilt.

An object of the present invention is to provide a reaction force adjusting structure that adjusts the tilting reaction force of a shearing blade unit that can be tilted back and forth and / or left and right. By switching the structure, the tilting reaction force can be adjusted according to the user's preference. The object is to provide an electric shaver that is easy to use and can be adjusted to change the shaving feeling of the shear blade unit.
An object of the present invention is to provide a lock structure and a reaction force adjustment structure for locking the shear blade unit so as not to be tilted, so that the lock state can be stably maintained in a state where the shear blade unit is locked by the lock structure, and the reaction force is adjusted. An object of the present invention is to provide an electric shaver that can simplify the structure and reduce the cost.

  In the electric razor according to the present invention, a shearing blade unit 8 having an inner blade 6 and an outer blade 7 is supported by a unit support 9 provided on the upper part of the main body case 1 so as to be tiltable. A lock structure that locks the shear blade unit 8 so as not to tilt and a reaction force adjustment structure that adjusts the tilt reaction force when the shear blade unit 8 tilts are provided between the main body case 1 and the shear blade unit 8. As shown in FIG. 1, the reaction force adjustment structure includes a switching adjustment body 41 provided in one of the main body case 1 and the shear blade unit 8, a reaction force adjustment body 42 provided in the other, and a switching adjustment body 41. An operation tool 43 for switching operation is provided. In a state in which the switching adjustment body 41 is switched with the operation tool 43, both the adjustment bodies 41 and 42 are engaged with each other or frictionally joined to generate a tilt reaction force. In a state where the shear blade unit 8 is locked and held by the lock structure, the switching adjustment body 41 and the reaction force adjustment body 42 are engaged or frictionally joined to hold the position of the shear blade unit 8 in cooperation with the lock structure.

  As shown in FIGS. 5 and 13, the central axis P <b> 2 of the reaction force adjusting body 42 is shifted back and forth with respect to the central axis P <b> 1 of the switching adjustment body 41 and the slide movement line L <b> 1 of the switching adjustment body 41.

  As shown in FIG. 5, the lock structure includes a movable lock body 27, a fixed lock body 28 provided on the central axis P1 of the switching adjustment body 41, and an operating tool for switching the movable lock body 27 between a locked state and an unlocked state. 29. In the reaction force application state in which the switching adjustment body 41 and the reaction force adjustment body 42 are engaged or friction-bonded to exert a tilting reaction force, the movable lock body 27 engages with the fixed lock body 28 against the tilting reaction force. At the same time, the shear blade unit 8 is tilted toward the center axis P1 side of the switching adjusting body 41 to lock the shearing blade unit 8 so that it cannot tilt forward and backward.

  The lock structure includes a movable lock body 27 provided in the main body case 1 that also serves as the switching adjustment body 41, a fixed lock body 28 provided in the shear blade unit 8, and an operation tool 29 for switching the movable lock body 27 up and down. I have. The reaction force adjustment structure includes a switching adjustment body 41 provided on the main body case 1 that is switched up and down, a reaction force adjustment body 42 that is supported by the shear blade unit 8 so as to be slidable back and forth, and a reaction force adjustment body 42. Return springs 46 and 47 are provided that are urged to move toward the neutral position. The movable lock body 27 and the switching adjustment body 41 are slid by the operating tools 29 and 43 to apply a reaction force in which the switching adjustment body 41 engages with the reaction force adjustment body 42, and the movable lock body 27 is a fixed lock body 28. And can be switched to a locked state.

  As shown in FIG. 1, the lock structure includes a rod-shaped movable lock body 27, a fixed lock body 28 including a concave portion that engages with and disengages from the upper end of the movable lock body 27, and an operation tool 29 that slides the movable lock body 27. I have. The reaction force adjusting body 42 of the reaction force adjusting structure is composed of a lower front slider 44 and an upper rear slider 45 which are guided and supported by the shearing blade unit 8 so as to be slidable in the front-rear direction. The return springs 46 and 47 are biased to move toward the neutral position. The front slider 44 and the rear slider 45 are formed with through holes 53 and 54 that engage with the switching adjustment body 41 in a vertically penetrating manner. The switching adjustment body 41 is in a low reaction force state where the switching adjustment body 41 engages with the connection hole 53 of the front slider 44, and the switching adjustment body 41 engages with both connection holes 53 and 54 of the front stage slider 44 and the rear stage slider 45. It is possible to switch to a high reaction force state. In the locked state, the movable lock body 27 is engaged with the fixed lock body 28.

  As shown in FIG. 8, the lock structure includes a movable lock body 27 supported by the main body case 1 so as to be slidable up and down, a fixed lock body 28 provided in the shear blade unit 8, and an operating tool 29 for sliding the movable lock body 27. It has. The reaction force adjustment structure includes a switching adjustment body 41 that slides up and down following the movable lock body 27, and a reaction force adjustment body 42 provided in the shear blade unit 8. The switching adjustment body 41 is provided with an elastic arm 73 that frictionally joins with the reaction force adjustment body 42 to generate a tilt reaction force. The movable lock body 27 and the switching adjustment body 41 are slid by the operating tools 29 and 43, and the reaction force application state in which the switching adjustment body 41 is frictionally joined to the reaction force adjustment body 42, and the movable lock body 27 is the fixed lock body 28. And can be switched to a locked state. In the reaction force application state, the shearing blade unit 8 that tilts back and forth receives the tilt reaction force due to the frictional resistance of the switching adjustment body 41 and the reaction force adjustment body 42.

  The elastic arm 73 is formed in an elastically deformable ring shape. The reaction force adjusting body 42 is formed by an arc surface having the center of tilt of the shearing blade unit 8 as the arc center.

  The fixed lock bodies 28 are formed at a plurality of locations on the unit frame 12. The engagement position of the movable lock body 27 with respect to the fixed lock body 28 is varied to lock and hold the shear blade unit 8 at different tilt angles.

  As shown in FIG. 13, the lock structure includes a movable lock body 27 slidably supported by the main body case 1, a fixed lock body 28 provided in the shearing blade unit 8, and an operating tool 29 for sliding the movable lock body 27. It has. The reaction force adjustment structure includes a switching adjustment body 41 that slides up and down following the movable lock body 27, and a reaction force adjustment body 42 provided in the shear blade unit 8. The switching adjustment body 41 is formed of an elastically deformable shaft body, and the reaction force adjustment body 42 is formed of an adjustment groove. The movable lock body 27 and the switching adjustment body 41 are operated by the operating tools 29 and 43 so that the switching adjustment body 41 is engaged with the reaction force adjustment body 42, and the movable lock body 27 is connected to the fixed lock body 28. The lock state can be switched to the engaged state. In the reaction force application state, the tilting shear blade unit 8 receives the tilt reaction force accompanying the elastic deformation of the switching adjustment body 41.

  The lock structure includes a movable lock body 27 supported by the main body case 1 so as to be slidable up and down, a fixed lock body 28 provided on the shear blade unit 8, an operation tool 29 supported by the main body case 1 so as to be slidable left and right, and an operation tool. 29 is provided with a cam structure that converts the left / right sliding operation of 29 into an up / down operation and transmits it to the movable lock body 27. The switching adjustment body 41 includes an elastic shaft 86 that elastically deforms following the tilting of the shear blade unit 8, and a passive shaft portion 87 that is provided at the upper end of the elastic shaft 86 and engages with the groove wall of the reaction force adjustment body 42. It has. The cam structure includes a passive cam body 80 that is slidably guided by the main body case 1, a return spring 81 that presses and urges the passive cam body 80, a plurality of cam surfaces 83 provided on the passive cam body 80, A cam roller 79 is provided on the operation tool 29 and pushes up the passive cam body 80 via the cam surface 83 while resisting the urging force of the return spring 81.

  As shown in FIG. 19, the lock structure includes a movable lock body 27 provided on the side of the shear blade unit 8 that also serves as the switching adjustment body 41, a fixed lock body 28 provided on the side of the main body case 1, and a movable lock body. An operation tool 29 is provided for switching 27 between a locked state and an unlocked state. The reaction force adjustment structure includes a switching adjustment body 41, a reaction force adjustment body 42 that is slidably guided and supported by the main body case 1, and return springs 46 and 47 that move and urge the reaction force adjustment body 42 toward the neutral position. I have. The movable lock body 27 and the switching adjustment body 41 are slid by the operation tool 29 so that the switching adjustment body 41 engages with the reaction force adjustment body 42, and the movable lock body 27 engages with the fixed lock body 28. It can be switched to the locked state. In the reaction force application state, the tilting shear blade unit 8 elastically deforms the return springs 46 and 47 and receives the tilt reaction force from the return springs 46 and 47.

  The reaction force adjusting body 42 of the reaction force adjusting structure is constituted by an upper front slider 44 and a lower rear slider 45, which are slidably guided and supported by the shear blade unit 8, respectively. The sliders 44 and 45 are urged to move toward the neutral position by return springs 46 and 47, respectively. The front slider 44 and the rear slider 45 are formed with through holes 53 and 54 that engage with the switching adjustment body 41 in a vertically penetrating manner. The switching adjustment body 41 is in a low reaction force state where the switching adjustment body 41 engages with the connection hole 53 of the front slider 44, and the switching adjustment body 41 engages with both connection holes 53 and 54 of the front stage slider 44 and the rear stage slider 45. It is possible to switch to a high reaction force state. In the locked state, the movable lock body 27 engages with the fixed lock body 28.

  In the electric razor of the present invention, the lock structure that locks the shear blade unit 8 so as not to be tiltable between the main body case 1 and the shear blade unit 8 and the tilt reaction force when the shear blade unit 8 tilts are adjusted. A reaction force adjustment structure was provided. In addition, the reaction force adjustment structure includes a switching adjustment body 41 provided in one of the main body case 1 and the shear blade unit 8, a reaction force adjustment body 42 provided in the other, and an operation tool for switching the switching adjustment body 41. 43. According to such a reaction force adjusting structure, in a state where the switching adjustment body 41 is switched by the operation tool 43, both the adjustment bodies 41 and 42 can be engaged with each other or frictionally joined to generate a tilting reaction force. Therefore, when using an electric razor, the switching adjustment body 41 is switched by the operation tool 43, whereby the tilting reaction force of the shear blade unit 8 is adjusted to the user's preference to change the shaving feeling. It is possible to improve usability compared to conventional electric razors. In a state where the shear blade unit 8 is locked and held by the lock structure, the switching adjustment body 41 and the reaction force adjustment body 42 are engaged or frictionally joined, and the shear blade unit 8 is held in cooperation with the lock structure. Therefore, the locked state of the shear blade unit 8 can be stably maintained. Thereby, it is possible to eliminate the unlocking of the shear blade unit 8 against the user's intention. Further, since the reaction force adjustment structure is configured by the switching adjustment body 41, the reaction force adjustment body 42, the operation tool 43, and the like that are engaged with each other or frictionally joined to each other, the structure of the reaction force adjustment structure is compared with the conventional adjustment structure. Simplify and reduce the cost of electric razors.

  The center axis P2 of the reaction force adjusting body 42 is shifted back and forth with respect to the center axis P1 of the switching adjusting body 41 and the slide movement line L1 of the switching adjusting body 41. According to such an electric razor, when the operating tool 43 is operated to switch the switching adjustment body 41 from the standby state to the reaction force application state, the switching adjustment body 41 is engaged with the reaction force adjustment body 42 and simultaneously sheared. The blade unit 8 can be tilted to the side that eliminates the previous front-back displacement. Therefore, the user can clearly know that the tilting reaction force is acting on the shearing blade unit 8 by visually observing the tilting of the shearing blade unit 8.

  The lock structure is constituted by the movable lock body 27, the fixed lock body 28 provided on the central axis P1 of the switching adjustment body 41, the operation tool 29 for switching the movable lock body 27, and the like, and the tilting reaction force is applied to the shear blade unit 8. In the applied reaction force application state, the movable lock body 27 is engaged with the fixed lock body 28 against the tilt reaction force. According to such a lock structure, simultaneously with the movable lock body 27 engaging with the fixed lock body 28, the shear blade unit 8 is tilted toward the central axis P1 of the switching adjustment body 41 while resisting the tilt reaction force. Can do. Therefore, the user can clearly know that the shearing blade unit 8 is locked so as not to tilt forward and backward by visually observing that the shearing blade unit 8 tilts toward the central axis P1. Further, as shown in FIG. 1, in the case of the reaction force adjusting structure in which the reaction force adjusting body 42 is moved and urged by the return springs 46 and 47, the movable lock body 27 is engaged with the fixed lock body 28. The movable lock body 27 is held in position by the spring force of the return springs 46 and 47, so that the locked state of the shear blade unit 8 can be kept stably.

  According to the electric razor in which the main body case 1 is provided with the movable lock body 27 that also serves as the switching adjustment body 41 and the shear blade unit 8 is provided with the fixed lock body 28, the movable lock body 27 is switched by sliding the operation tool 29. The adjustment body 41 can be engaged with the reaction force adjustment body 42 to switch to the reaction force application state. In addition, after the switching adjustment body 41 is switched to the reaction force application state, the movable lock body 27 can be engaged with the fixed lock body 28 to switch to the locked state. In this way, when the movable lock body 27 also serves as the switching adjustment body 41 and the operation tool 29 serves also as the operation tool 43 of the switching adjustment body 41, the structure of the reaction force adjustment structure is simplified and the manufacturing cost of the electric shaver is reduced. Can be reduced. In the locked state, the movable lock body 27 is engaged with the fixed lock body 28, and the switching adjustment body 41 and the reaction force adjustment body 42 are engaged so that the shear blade unit 8 cooperates with the lock structure. Since the position is maintained, the locked state of the shear blade unit 8 can be maintained stably.

  According to the reaction force adjusting structure in which the reaction force adjusting body 42 is configured by a front slider 44 and a rear slider 45 that are slidable back and forth, the switching adjustment body 41 is engaged with the front slider 44 or both sliders 44 and 45 are engaged. Can be switched to a low reaction force state and a high reaction force state. Further, by sliding the movable lock body 27 beyond the high reaction force state, the movable lock body 27 can be engaged with the fixed lock body 28 to lock the shear blade unit 8 so that it cannot tilt. According to such an electric razor, the reaction force in the low reaction force state and the reaction force in the high reaction force state can be freely set by adjusting the spring force of the return springs 46 and 47 of the front slider 44 and the rear slider 45. be able to. Therefore, it is possible to obtain an electric shaver excellent in usability that can exhibit a fine tilt reaction force according to the user's preference.

  According to the reaction force adjustment structure in which the elastic arm 73 of the switching adjustment body 41 and the reaction force adjustment body 42 are frictionally joined to exert a tilt reaction force, regardless of whether the shear blade unit 8 is tilted or not, the operation is simply performed. By simply operating the tool 43, the elastic arm 73 is brought into close contact with the reaction force adjusting body 42, and the tilting reaction force can be applied to the shear blade unit 8, or the tilting reaction force can be increased or decreased. Accordingly, whiskers can be cut smoothly while the tilt reaction force of the shear blade unit 8 is switched between large and small according to the portion of the whiskers to be cut. Further, by operating the operation tool 43, the shaving comfort of the shearing blade unit 8 can be adjusted by switching the reaction force adjusting structure between the standby state, the low reaction force state, and the high reaction force state. Can be improved. Furthermore, after the switching adjustment body 41 is switched to the high reaction force state, the movable lock body 27 can be engaged with the fixed lock body 28 to lock the shear blade unit 8 so that it cannot tilt.

  According to the reaction force adjustment structure in which the elastic arm 73 is formed in an elastically deformable ring shape and the reaction force adjustment body 42 is formed by an arcuate surface, the tilt reaction force when the shear blade unit 8 tilts to one side and the other The tilting reaction force when tilting toward can be equalized. Therefore, when cutting the whiskers while reciprocating the shearing blade unit 8 along the skin surface, the frictional force between the shearing blade unit 8 and the skin surface can be prevented from varying during forward movement and backward movement. The beard can be cut effectively.

  If the fixed lock bodies 28 are formed at a plurality of locations on the unit frame 12, the shearing blade unit 8 is locked and held at different tilt angles by changing the engagement position of the movable lock body 27 with respect to the fixed lock body 28. The beard cutting can be performed. For example, it is possible to easily perform a beard cutting by changing the posture of the shearing blade unit 8 according to the user's preference in accordance with the difference in the site for cutting the beard.

  According to the reaction force adjustment structure in which the switching adjustment body 41 is formed of an elastically deformable shaft and the reaction force adjustment body 42 is formed of a vertically long adjustment groove, when the shear blade unit 8 tilts, the switching adjustment body 41 It is possible to apply a tilting reaction force to the shearing blade unit 8 by elastically deforming. Further, by switching the switching adjustment body 41 with the operation tool 43 and changing the engagement depth between the switching adjustment body 41 and the reaction force adjustment body 42, the reaction force adjustment structure is changed from the low reaction force state to the high reaction force. It can be switched to the state. Furthermore, by sliding the operating tool 43 beyond the high reaction force state, the movable lock body 27 can be engaged with the fixed lock body 28, and the shearing blade unit 8 can be locked and held without being tilted. According to such an electric razor, the structure of the reaction force adjusting structure and the lock structure can be simplified, and the manufacturing cost of the electric razor can be reduced. In the low reaction force state and the high reaction force state, since the switching adjustment body 41 and the reaction force adjustment body 42 are engaged with each other, the switching reaction of the switching adjustment body 41 can be smoothly performed to increase or decrease the tilt reaction force.

  When the switching adjustment body 41 is configured by the elastic shaft 86 and the passive shaft portion 87, when the shear blade unit 8 tilts, the elastic deformation of the elastic shaft 86 engages with the groove wall of the reaction force adjustment body 42. Is transmitted to the shearing blade unit 8 via. In this state, since only the passive shaft portion 87 is engaged with the groove wall of the reaction force adjusting body 42, it is possible to prevent an excessive tilting force from acting on the elastic shaft 86. When the cam structure is constituted by a passive cam body 80 that can slide up and down, a return spring 81, a plurality of cam surfaces 83 provided on the passive cam body 80, a cam roller 79 provided on the operation tool 29, and the like, the operation tool 29 ( 43) The passive cam body 80 can be moved up and down by the slide operation 43) to switch the reaction force adjusting structure between the low reaction force state and the high reaction force state. Furthermore, by sliding the operation tool 29 (43) beyond the high reaction force state, the movable lock body 27 can be engaged with the fixed lock body 28, and the shear blade unit 8 can be locked and held so as not to tilt. According to such an electric razor, the reaction force adjusting structure can be switched between the standby state, the low reaction force state, and the high reaction force state to adjust the shaving feeling of the shear blade unit 8, so that the usability of the electric razor can be improved. Furthermore, after the switching adjustment body 41 is switched to the high reaction force state, the movable lock body 27 can be engaged with the fixed lock body 28 to lock the shear blade unit 8 so that it cannot tilt. In a state where the shear blade unit 8 is locked and held, the switching adjustment body 41 and the reaction force adjustment body 42 are engaged to hold the position of the shear blade unit 8 in cooperation with the lock structure. The state can be kept stable.

  When the movable lock body 27 that also serves as the switching adjustment body 41 is provided on the shear blade unit 8 side, and the fixed lock body 28 and the reaction force adjustment body 42 are provided on the main body case 1 side, the reaction force adjustment body 42 that slides left and right and the return Since the springs 46 and 47 can be accommodated in the main body case 1, it is possible to prevent the structure of the shear blade unit 8 from becoming complicated. In the reaction force application state, the tilting shear blade unit 8 elastically deforms the return springs 46 and 47 and receives the tilt reaction force from the return springs 46 and 47. The return to the neutral position can be performed smoothly with good response. Since the movable lock body 27 also serves as the switching adjustment body 41 and the operation tool 29 serves also as the operation tool 43 of the switching adjustment body 41, the structure of the reaction force adjustment structure can be simplified and the manufacturing cost of the electric razor can be reduced. In the locked state, the movable lock body 27 is engaged with the fixed lock body 28, and the switching adjustment body 41 and the reaction force adjustment body 42 are engaged so that the shear blade unit 8 cooperates with the lock structure. Since the position is maintained, the locked state of the shear blade unit 8 can be maintained stably.

  According to the reaction force adjusting structure in which the reaction force adjusting body 42 is configured by a front slider 44 and a rear slider 45 that are slidable back and forth, the switching adjustment body 41 is engaged with the front slider 44 or both sliders 44 and 45 are engaged. Can be switched to a low reaction force state and a high reaction force state. Further, by sliding the movable lock body 27 beyond the high reaction force state, the movable lock body 27 can be engaged with the fixed lock body 28 to lock the shear blade unit 8 so that it cannot tilt. According to such an electric razor, the reaction force in the low reaction force state and the reaction force in the high reaction force state can be freely set by adjusting the spring force of the return springs 46 and 47 of the front slider 44 and the rear slider 45. be able to. Therefore, it is possible to obtain an electric shaver excellent in usability that can exhibit a fine tilt reaction force according to the user's preference.

It is a vertical side view of the electric razor which concerns on Example 1 of this invention. 1 is a front view of an electric razor according to Embodiment 1. FIG. It is a vertical front view of the electric razor which concerns on Example 1. FIG. It is the vertical front view which expanded the principal part of FIG. It is the sectional view on the AA line in FIG. It is the vertical side view which switched the reaction force adjustment structure which concerns on Example 1 to the low reaction force state. It is the vertical side view which switched the reaction force adjustment structure which concerns on Example 1 to a high reaction force state. It is a partially broken side view of the electric razor which concerns on Example 2 of this invention. 6 is a front view of an electric razor according to Embodiment 2. FIG. It is the BB sectional drawing in FIG. 9 which switched the reaction force adjustment structure which concerns on Example 2 to the low reaction force state. It is the vertical side view of the position equivalent to FIG. 10 which switched the reaction force adjustment structure which concerns on Example 2 to a high reaction force state. It is CC sectional view taken on the line in FIG. It is a partially broken side view of the electric razor which concerns on Example 3 of this invention. 10 is a front view of an electric razor according to Embodiment 3. FIG. It is the vertical side view which switched the reaction force adjustment structure which concerns on Example 3 to the low reaction force state. It is the vertical side view which switched the reaction force adjustment structure which concerns on Example 3 to a high reaction force state. It is the vertical side view which switched the lock structure concerning Example 3 to the lock state. It is a vertical side view which shows another Example which changed the lock structure of Example 3. FIG. It is a front view of the electric shaver which concerns on Example 4 of this invention. It is the vertical front view which switched the reaction force adjustment structure which concerns on Example 4 to the low reaction force state. It is the vertical front view which switched the lock structure concerning Example 4 to the lock state.

Example 1 FIGS. 1 to 7 show Example 1 of an electric shaver according to the present invention. In the present invention, “front and rear”, “left and right”, and “up and down” follow the cross arrows shown in FIG. 2 and the character display indicating the direction. 2 and 3, the electric razor includes a main body case 1 that also serves as a grip and a razor head 2 provided on the upper portion of the main body case 1, and is configured as a reciprocating electric razor. A motor 3 and a secondary battery 4 are disposed inside the main body case 1, and a switch button 5 for starting or stopping the motor 3 is provided on the front surface of the case. The razor head 2 is provided with a shearing blade unit 8 having an inner blade 6 and an outer blade 7, and the shearing blade unit 8 can be tilted forward and backward by a pair of left and right unit supports 9 provided at the upper part of the main body case 1. I support it.

  The shear blade unit 8 includes a unit frame 12, an inner blade holder 13 that supports the inner blade 6, an outer blade holder 14 that supports the outer blade 7, and a vibrator 15 accommodated inside the unit frame 12. It is. The unit frame 12 has a pair of left and right side frames 16 and a center frame 17 and is configured in a reverse portal shape, and a tilting shaft 18 provided on the outer surface of the upper side of the side frame 16 is supported by the unit support 9. Thus, the entire shear blade unit 8 can be tilted back and forth about the tilting shaft 18. The lower surface of the unit frame 12 and the upper surface of the main body case 1 between the unit supports 9 are each formed by an arc surface having the center of the tilt shaft 18 (center of tilt) as the arc center, and are vertically moved with a slight gap. Opposite to.

  The vibrator 15 is housed inside the central frame 17, and a drive shaft 20 that outputs reciprocating power to the inner blade holder 13 is provided on the upper surface side, and is fixed to the output shaft of the motor 3 on the lower surface side. The eccentric cam 21 is provided with a cam groove 22 that is reciprocated to the left and right. The upper surface of the central frame 17 that accommodates the vibrator 15 is covered with a cover 23, and a gap between the cover 23 and the drive shaft 20 is sealed with a rubber packing 24.

  A lock structure is provided between the main body casing 1 and the unit frame 12 in order to lock and hold the shearing blade unit 8 tilting back and forth so that it cannot tilt back and forth. Further, in order to give an appropriate tilting reaction force to the shearing blade unit 8 and change the shaving feeling of the shearing blade unit 8 according to the user's preference, the tilting reaction force is reduced between the main body case 1 and the unit frame 12. A reaction force adjustment structure that adjusts the reaction force to a high reaction force is provided.

  As shown in FIGS. 1 and 4, the lock structure is disposed on one side of the unit frame 12 corresponding to the movable lock body 27, and a linear bar-shaped movable lock body 27 disposed on the upper side of the main body case 1. The fixed lock body 28, the operation tool 29 for switching the movable lock body 27 between a locked state and an unlocked state, and a moderation structure are configured. The fixed lock body 28 is recessed on the inner surface of the ceiling wall of the slide section 48 described later. In order to slide up and down the movable lock body 27 and the moderation structure, a guide section 30 is provided inside one side of the main body case 1, and the movable lock body 27 and the moderation structure are guided and supported by the front and rear walls and the left and right walls. An entrance / exit 31 for guiding and supporting the movable lock body 27 is opened in the ceiling wall of the guide section 30, and a knob groove 32 for exposing the operation tool 29 to the outside of the case is opened in the outer wall of the guide section 30. is there. An operation recess 33 is formed in the lower portion of the unit support 9, and the operation tool 29 is accommodated in the recess 33 to prevent the operation tool 29 from protruding outside the outline of the main body case 1. ing.

  As shown in FIG. 1, the moderation structure includes a quadrangular moderation base 35 continuous to the lower end of the movable lock body 27, an elastically deformable moderation arm 36 provided before and after the moderation base 35, and a midway in the vertical direction of the moderation arm 36. It comprises a moderation protrusion 37 projecting from the portion and four pairs of upper and lower moderation recesses 38 that are recessed on the opposing surfaces of the left and right walls of the guide section 30. The movable lock body 27, the operation tool 29, and the moderation structure are made of an integrally molded plastic molded product, and a knob-like operation tool 29 projects from the center of the outer surface of the moderation base 35.

  The reaction force adjustment structure includes a switching adjustment body 41, a reaction force adjustment body 42 disposed on the lower side of the unit frame 12 corresponding to the switching adjustment body 41, an operation tool 43 for switching the switching adjustment body 41, and the like. Configure. In this embodiment, the movable lock body 27 described above also serves as the switching adjustment body 41, and the operation tool 29 having the lock structure also serves as the operation tool 43 having the reaction force adjustment structure. In the following description, the movable lock body 27 and the switching adjustment body 41 will be described as necessary. The reaction force adjusting body 42 includes a lower front slider 44 and an upper rear slider 45 disposed in the unit frame 12, and a pair of compression coil type return springs 46 disposed before and after the sliders 44 and 45. -47 is provided. These return springs 46 and 47 function as return springs that urge the shear blade unit 8 to move toward the neutral position. In order to accommodate both the sliders 44 and 45 and the return springs 46 and 47, a slide section 48 is provided between the joint surfaces of the side frame 16 and the central frame 17, and guide grooves 49 for the front slider 44 are formed above and below the slide section 48. The guide grooves 50 for the rear slider 45 are each formed in an arcuate groove shape.

  The front slider 44 and the rear slider 45 are made of a plastic block whose upper and lower surfaces are formed in a partial arc shape, and connecting holes 53 and 54 that engage with the switching adjustment body 41 are formed in a vertically penetrating manner at the center of the block. . In the lower openings of the connection holes 53 and 54, guide surfaces 55 and 56 that facilitate entry engagement with the connection holes 53 and 54 of the switching adjustment body 41 are formed obliquely. A similar guide surface 57 is also formed in the lower opening of the fixed lock body 28 described above.

  The reaction force adjustment structure can be switched between a standby state, a low reaction force state, and a high reaction force state by operating the operating tool 43 (29) up and down. FIG. 5 shows a standby state, and since the upper end of the switching adjustment body 41 at this time is located inside the entrance / exit 31, the shearing blade unit 8 can freely tilt back and forth around the tilting shaft 18, No tilt reaction force acts on the shear blade unit 8 when tilting back and forth. In the low reaction force state, as shown in FIG. 6, the upper portion of the switching adjustment body 41 is engaged with the connection hole 53 of the front slider 44. Therefore, when the shearing blade unit 8 tilts back and forth, either one of the front and back return springs 46 is compressed and deformed, so that the tilting reaction force corresponding to the elastic deformation amount of the return spring 46 acts on the shearing blade unit 8. To do. In the high reaction force state, as shown in FIG. 7, the switching adjustment body 41 engages with the connection holes 53 and 54 of the front slider 44 and the rear slider 45. Therefore, when the shear blade unit 8 tilts back and forth, the pair of upper and lower return springs 46 and 47 are compressed and deformed, so that the shear blade unit 8 has a larger tilt corresponding to the amount of elastic deformation of the return springs 46 and 47. Reaction force acts. In the low reaction force state and the high reaction force state, the tilt reaction force increases in proportion to the increase in the tilt angle of the shear blade unit 8. This is because the upper and lower return springs 46 and 47 are greatly compressed and deformed as the tilt angle increases.

  As shown in FIG. 1, the lock structure is such that the operation tool 29 (43) is slid upward from the standby state to the uppermost position beyond the high reaction force state, and the upper part of the movable lock body 27 is engaged with the fixed lock body 28. By combining, it can be switched to the locked state. The upper and lower sides of the movable lock body 27 in the locked state are engaged and held by the fixed lock body 28 and the entrance / exit 31, and the upper and lower middle portions of the movable lock body 27 are engaged and held by the front stage slider 44 and the rear stage slider 45. . That is, in a state where the shear blade unit 8 is locked and held, the switching adjustment body 41 and the reaction force adjustment body 42 are engaged, and the shear blade unit 8 is held in position in cooperation with the lock structure. Therefore, even if an external force is applied, the shearing blade unit 8 does not tilt in the front-rear direction or the left-right direction, and the locked state can be maintained stably. In the standby state, the low reaction force state, the high reaction force state, and the lock state, the moderation protrusion 37 of the moderation structure drops into the moderation recess 38 and engages with the movable lock body 27 and the switching adjustment body 41. Restricts vertical movement.

  As described above, the shear blade unit 8 is urged to move toward the neutral position by the return springs 46 and 47. Therefore, at the same time when the tilting external force is released, the shearing blade unit 8 swings back to the neutral position, and the elastic forces of the front and rear return springs 46 and 47 are balanced. In this neutral state, as shown in FIG. 5, the center axis of the front slider 44 and the rear slider 45, that is, the center axis P <b> 2 of the reaction force adjuster 42 is located on the center axis of the shear blade unit 8.

  In order to clearly notify the user that the switching adjustment body 41 is engaged with the reaction force adjustment body 42 and to clearly notify the user that the movable lock body 27 is engaged with the fixed lock body 28, the switching adjustment body 41 is provided. Center axis P1 and the center axis P2 of the reaction force adjusting body 42 are shifted back and forth. A central axis P1 of the switching adjustment body 41 is a movement line L1 of the switching adjustment body 41, and the center of the switching adjustment body 41 slides up and down along the movement line L1.

  Specifically, as shown in FIG. 5, the front and rear center positions of the guide grooves 49 and 50 for both sliders 44 and 45 are shifted to the front side from the central axis P1 of the switching adjustment body 41, so that both sliders in the neutral state. The center axis P2 passing through the centers of the connection holes 53 and 54 of 44 and 45 is inclined forward of the center axis P1. As described above, when the center axis P1 of the switching adjustment body 41 and the center axis P2 of the reaction force adjustment body 42 are shifted back and forth, each slider 44 is in a state where the switching adjustment body 41 is engaged with the connection holes 53 and 54. Since 45 is drawn toward the switching adjustment body 41, the return springs 46 and 47 on the rear side can be compressed and deformed so that the connecting holes 53 and 54 are brought into close contact with the switching adjustment body 41. Further, as the sliders 44 and 45 are drawn toward the switching adjustment body 41 (rear side), the shear blade unit 8 is tilted to the side where the front / rear displacement is eliminated. Therefore, the user can clearly know that the tilting reaction force is acting on the shearing blade unit 8 by visually observing that the shearing blade unit 8 tilts backward.

  The shear blade unit 8 can be tilted also when the movable lock body 27 is switched from the reaction force application state and engaged with the fixed lock body 28. When the reaction force adjustment structure is in a high reaction force state, as shown in FIG. 7, the longitudinal center (center axis P2) of the shear blade unit 8 is located behind the center axis P1 of the switching adjustment body 41. Yes. When the movable lock body 27 is raised from this state, the upper end front corner comes into contact with the guide surface 57 of the fixed lock body 28. At this time, the unit frame 12 tilts forward while resisting the spring force of the return springs 46 and 47, and finally the upper part of the movable lock body 27 engages with the fixed lock body 28. Therefore, the user can clearly know that the shear blade unit 8 has been switched to the locked state by visually observing that the shear blade unit 8 is tilted forward.

  According to the electric shaver configured as described above, the reaction force adjusting structure can be switched between the standby state, the low reaction force state, and the high reaction force state by sliding the operation tool 29 (43). Therefore, when shaving, the tilt reaction force does not act according to the user's preference, the tilt reaction force of the shear blade unit 8 is switched to a soft reaction, and the high reaction force state is a soft touch. Since the shaving feeling of the shear blade unit 8 can be adjusted, the usability of the electric razor can be improved.

  When the operating tool 29 (43) is slid upward to the uppermost position beyond the high reaction force state and the movable lock body 27 is engaged with the fixed lock body 28, the lock structure is switched to the lock state, and the shearing blade The unit 8 can be locked and held so as not to tilt forward and backward. The upper and lower sides of the movable lock body 27 in this locked state are engaged and held by the fixed lock body 28 and the entrance / exit 31, and the upper and lower middle parts of the movable lock body 27 are engaged and held by the front stage slider 44 and the rear stage slider 45. Yes. Therefore, even if an external force is applied, the shearing blade unit 8 does not tilt in the front-rear direction or the left-right direction, and the locked state can be maintained stably. Furthermore, in the above-described embodiment, the movable lock body 27 also serves as the switching adjustment body 41, and the operation tool 29 having the lock structure also serves as the operation tool 43 having the reaction force adjustment structure. Therefore, the structure of the reaction force adjustment structure is simplified. There is also an advantage that the cost can be reduced.

(Example 2) FIGS. 8-12 shows Example 2 of the electric shaver which concerns on this invention. The electric razor according to the second embodiment is different from the electric razor according to the first embodiment in that the electric razor is configured as a rotary electric razor. Further, the lock structure and the reaction force adjusting structure of the shear blade unit 8 are different from those of the first embodiment. It is different from a razor.

  As shown in FIG. 9, the shear blade unit 8 is provided with an inner blade 6 that is driven to rotate about the horizontal axis. Inside the unit frame 12, the motor 3 that is horizontally disposed and the rotation of the motor 3 are arranged. A gear train 60 for transmitting power to the inner blade 6 is arranged. The rotation axis of the inner blade 6 is rotatably supported by the side frame 16 of the unit frame 12, and the secondary battery 4 is disposed inside the main body case 1. As in the first embodiment, the shearing blade unit 8 is supported by a pair of left and right unit supports 9 provided on the upper part of the main body case 1 so as to be tiltable back and forth. In order to urge the shear blade unit 8 tiltable back and forth to the neutral position, as shown in FIG. 8, a spring receiving piece 58 is provided on the unit frame 12 side, and the spring receiving piece 58 and the unit support 9 are A return spring 46 is disposed between the front and rear walls. Reference numeral 59 denotes a relief opening for the spring receiving piece 58 opened in the unit support 9.

  8 to 12, the lock structure is rotatably supported by the movable lock body 27 provided in the main body case 1, the fixed lock body 28 provided in the unit frame 12, and the main body case 1. The operation tool 29, a link body 61 that converts the rotational movement of the operation tool 29 into a reciprocating motion and transmits it to the movable lock body 27, a moderation structure for the operation tool 29, and the like. The movable lock body 27 is composed of a vertically long rod-like body whose upper end is rounded, and is supported by a pair of front and rear guide frames 62 provided on the main body case 1 together with a switching adjustment body 41 described later so as to be slidable up and down. As shown in FIG. 10, the fixed lock body 28 is composed of seven circular arc recesses formed on the lower surface of the unit frame 12, and the shear blade unit 8 is tilted back and forth to engage the movable lock body 27 and the fixed lock body 28. The shearing blade unit 8 can be locked and held at different tilt angles by changing the alignment positions.

  The operation tool 29 includes an operation dial 64 exposed on one outer surface of the main body case 1 and a dial shaft 65 integral with the operation dial 64, and also serves as the operation tool 43 for a reaction force adjustment structure. A connecting pin 66 is provided at the inner end of the dial shaft 65. This pin 66 is connected to the lower part of the link body 61, and the upper part of the link body 61 is connected to the movable lock body 27 via the connecting pin. The rotation operation of the operation dial 64 is converted into an up / down operation by the link body 61 and transmitted to the movable lock body 27. A moderation structure is provided to stop and hold the operation dial 64 every time the operation dial 64 is rotated clockwise by a predetermined angle (30 degrees) from the standby state shown in FIG. Further, an index 67 for displaying the degree of rotation is provided on the outer surface of the operation dial 64.

  The moderation structure includes a moderation arm 69 made of a leaf spring disposed at a lower portion of the peripheral surface of the dial shaft 65 and a moderation recess 70 formed in a recess on the peripheral surface of the dial shaft 65. A moderation protrusion 71 is provided in one piece so as to be brought into engagement with 70. In this embodiment, four moderation recesses 70 are formed on the peripheral surface of the dial shaft 65, and each time the operation dial 64 rotates by a certain angle, the moderation protrusion 71 engages with the moderation recess 70, and the operation dial 64. The position can be held so that it cannot freely rotate.

  The reaction force adjustment structure includes a switching adjustment body 41 that is supported by a guide frame 62 of the main body case 1 so as to be vertically slidable, and a reaction force adjustment body 42 provided on the lower surface of the unit frame 12. The movable lock body 27 described above is formed integrally with the switching adjustment body 41. Further, an elastic arm 73 is integrally provided on the upper surface of the switching adjustment body 41 so as to generate a tilting reaction force by frictional joining with the reaction force adjustment body 42. The elastic arm 73 is formed of an elastically deformable ring formed integrally with the switching adjustment body 41, and the upper surface of the elastic arm 73 circumscribes the reaction force adjustment body 42 with a weak force in the standby state shown in FIG. The reaction force adjusting body 42 is formed by an arc surface with the center of tilt of the shearing blade unit 8 as the arc center. As described above, in the second embodiment, the movable lock body 27 and the switching adjustment body 41 are formed as separate members.

  The reaction force adjusting structure can be switched to a standby state, a low reaction force state, and a high reaction force state by rotating the operation tool 29. FIG. 10 shows a standby state. At this time, the elastic arm 73 of the switching adjustment body 41 circumscribes the reaction force adjustment body 42 having a downward projecting curved shape with a weak force to bring the shearing blade unit 8 to the neutral position. Holds the position. However, when an external force exceeding the elastic deformation force of the elastic arm 73 is applied to the shear blade unit 8, the shear blade unit 8 can be tilted forward or backward. When the operation dial 64 is rotated 30 degrees from the standby state, the switching adjustment body 41 is pushed up together with the movable lock body 27, so that the elastic arm 73 is elastically deformed into a flat elliptical shape and switched to the low reaction force state. Instead, the tilt reaction force corresponding to the elastic deformation amount of the elastic arm 73 acts on the shearing blade unit 8.

  When the operation dial 64 is further rotated 30 degrees from the low reaction force state, the reaction force adjustment structure is switched to the high reaction force state. In the high reaction force state, the switching adjustment body 41 is further pushed up together with the movable lock body 27, and the elastic arm 73 is further elastically deformed into a flat elliptical shape, so that a larger tilt reaction force than in the low reaction force state is sheared. It acts on the blade unit 8. In the low reaction force state and the high reaction force state, a rotational moment in the counterclockwise direction accompanying the elastic deformation of the elastic arm 73 acts on the operation dial 64, but the moderation arm 68 resists the previous rotational moment. Thus, the engagement state between the moderation recess 70 and the moderation protrusion 71 is kept, so that the operation dial 64 does not rotate. Further, in the low reaction force state and the high reaction force state, the compression deformation of the return spring 46 increases in proportion to the increase in the tilt angle of the shear blade unit 8, so that the tilt reaction acting on the shear blade unit 8 is increased. The force increases in proportion to the degree of tilt.

  As shown in FIG. 11, in the lock structure, the operation dial 64 is rotated from the standby state to the rotation limit position beyond the high reaction force state, and the upper portion of the movable lock body 27 is engaged with the fixed lock body 28. Can be switched to the locked state. The elastic arm 73 at this time is elastically deformed more flatly than the elastic arm 73 in the high reaction force state, but the amount of vertical movement of the switching adjustment body 41 between the high reaction force state and the locked state is small. The degree of elastic deformation of 73 is negligible. Since seven fixed lock bodies 28 are provided, the shearing blade unit 8 can be locked and held in the tilting position so as not to be tilted in the neutral position, and the shearing blade unit is tilted at each of the three tilting positions in the neutral position and the three rearward positions. 8 can be locked and cannot be tilted, and the usability of the electric razor can also be improved in this respect. Since the operation dial 64 is restricted by a stopper (not shown) in the standby state and the locked state, the operation dial 64 is not operated to rotate beyond the above states.

  As described above, in the second embodiment, by turning the operation tool 29, the reaction force adjusting structure is switched between the standby state, the low reaction force state, and the high reaction force state, and the shear blade unit 8 is shaved. Since the comfort can be adjusted, the usability of the electric razor can be improved as in the first embodiment. Further, since the switching adjustment body 41 is frictionally joined to the reaction force adjustment body 42 to maintain the reaction force application state, the operation dial 64 is rotated even when the shear blade unit 8 is tilted back and forth. Therefore, the tilt reaction force of the shear blade unit 8 can be switched between large and small according to the portion of the whiskers to be cut. Since other structures are the same as those of the first embodiment, the same members are denoted by the same reference numerals, and the description thereof is omitted. The same applies to the following embodiments.

Example 3 FIGS. 13 to 17 show Example 3 of an electric shaver according to the present invention. The electric razor according to the third embodiment is configured as a reciprocating electric razor as in the first embodiment, and the lock structure and the reaction force adjusting structure of the shear blade unit 8 are the electric razors according to the first and second embodiments. Is different.

  The lock structure in this embodiment includes a movable lock body 27 provided at the front upper portion of the passive cam body 80, a fixed lock body 28 formed in a recess on the lower surface of the unit frame 12 corresponding to the movable lock body 27, and an operating tool. 29 and a cam structure. The movable lock body 27 is supported by the main body case 1 so as to be slidable up and down indirectly via a passive cam body 80 described later.

  In FIG. 13, the operating tool 29 is guided and supported by a guide groove 76 provided in the main body case 1 so as to be slidable back and forth. Tells the force adjustment structure. The operation tool 29 includes a slide knob 77 exposed outside the guide groove 76, a round shaft-shaped roller shaft 78 provided on the inner surface thereof, and a cam roller 79 rotatably supported by the roller shaft 78. 13, the roller shaft 78 can slide back and forth between a standby state where the roller shaft 78 is positioned at the front end of the guide groove 76 and a locked state where the roller shaft 78 is positioned at the rear end of the guide groove 76. The cam structure is configured such that a plate-like passive cam body 80 that is guided and supported by the previous cam roller 79, a guide frame 75 of the main body case 1 so as to be slidable up and down, and urges the passive cam body 80 to be pushed down toward a standby position. It consists of a return spring 81 and the like. On the lower surface of the passive cam body 80, there are four engagement recesses 82 into which the cam roller 79 falls and engages, and three tilts downward from the front engagement recesses 82 toward the rear engagement recesses 82. A cam surface 83 is formed. The cam structure exhibits a moderation function equivalent to that of the moderation structure by the cam roller 79 dropping and engaging with each engagement recess 82.

  The reaction force adjustment structure includes a rod-shaped switching adjustment body 41 projecting from the upper surface of the passive cam body 80 and a vertically long adjustment groove formed on the unit frame 12 adjacent to the rear side of the fixed lock body 28. A reaction force adjusting body 42 is provided. The switching adjustment body 41 has a vertically long elastic shaft 86 that elastically deforms following the forward and backward tilting of the shear blade unit 8 and a spherical shape that is provided at the upper end of the elastic shaft 86 and engages with the groove wall of the reaction force adjustment body 42. And a passive shaft portion 87.

  In order to clearly notify the user that the switching adjustment body 41 has been engaged with the reaction force adjustment body 42 and that the movable lock body 27 has been engaged with the fixed lock body 28, The central axis P2 of the force adjusting body 42 is shifted back and forth in a parallel state. Specifically, in the standby state shown in FIG. 13, the central axis P <b> 1 of the switching adjustment body 41 is positioned behind the central axis P <b> 2 of the reaction force adjustment body 42. In this state, the movable lock body 27 and the fixed lock body 28 face each other vertically with a large gap therebetween. Thus, in Example 3, the movable lock body 27 and the switching adjustment body 41 were formed as separate members. A central axis P1 of the switching adjustment body 41 is a movement line L1 of the switching adjustment body 41, and the center of the switching adjustment body 41 slides up and down along the movement line L1.

  By sliding the slide knob 77, the reaction force adjusting structure can be switched between a standby state, a low reaction force state, and a high reaction force state. Furthermore, by further sliding the slide knob 77 from the high reaction force state, the lock structure can be switched to the locked state. FIG. 13 shows a standby state, and since the passive shaft portion 87 of the switching adjusting body 41 at this time is located inside the entrance / exit 31, the shearing blade unit 8 can freely move back and forth around the tilting shaft 18. Tilt can be performed, and no tilting reaction force acts on the shearing blade unit 8 when tilting back and forth.

  When the slide knob 77 is slid backward from the standby state, the cam surface 83 is pushed up against the urging force of the return spring 81 by the roller shaft 78, and the roller shaft 78 is engaged with the second engagement recess 82 from the top. Accordingly, the passive cam body 80 and the switching adjustment body 41 are switched to the low reaction force state. In the low reaction force state, as shown in FIG. 15, the passive shaft portion 87 of the switching adjustment body 41 engages with the groove lower portion of the reaction force adjustment body 42. In the process in which the passive shaft portion 87 engages with the reaction force adjusting body 42, the shearing blade unit 8 is slightly tilted counterclockwise about the tilting shaft 18 so that the front and rear of the previous center axis lines P1 and P2. Absorb the deviation. Therefore, the user can clearly know that the tilting reaction force is acting on the shearing blade unit 8 by visually observing that the shearing blade unit 8 tilts backward. When the shear blade unit 8 tilts forward or backward in the low reaction force state, the elastic shaft 86 of the switching adjustment body 41 is elastically deformed to generate a tilt reaction force, and the tilt reaction force is proportional to the tilt amount of the shear blade unit 8. Then increase.

  When the slide knob 77 is slid backward from the low reaction force state, the passive cam body 80 is pushed up by the roller shaft 78, and the roller shaft 78 engages with the third engaging recess 82 from the top, whereby the passive cam body 80 and the switching adjusting body 41 are switched to the high reaction force state. In the high reaction force state, as shown in FIG. 16, the passive shaft portion 87 of the switching adjustment body 41 is engaged with the groove wall in the middle of the reaction force adjustment body 42. Therefore, the shear blade unit 8 at the neutral position in the high reaction force state further tilts counterclockwise from the neutral position in the low reaction force state. In this engaged state, when the shear blade unit 8 tilts forward or backward from the neutral position, the elastic shaft 86 of the switching adjustment body 41 is elastically deformed to generate a tilt reaction force, and the tilt reaction force is tilted by the shear blade unit 8. It increases in proportion to the amount.

  In the high reaction force state, the tilting force required to elastically deform the elastic shaft 86 is larger than that in the low reaction force state. In the high reaction force state, the elastic shaft 86 is inserted deeper into the groove of the reaction force adjusting body 42 than in the low reaction force state, and the engagement position between the passive shaft portion 87 and the groove wall of the reaction force adjusting body 42. However, it exists in the high position above the engagement position of both 42 and 87 of a low reaction force state. In this state, the tilt reaction force when the shear blade unit 8 starts to tilt back and forth is relatively small. However, when the tilting angle of the shear blade unit 8 increases, the elastic shaft 86 deforms into a curved shape and comes into contact with the groove wall of the reaction force adjusting body 42. Therefore, the deformation stress of the elastic shaft 86 becomes the largest and exhibits the largest deformation reaction force to maintain a high reaction force state.

  When the slide knob 77 is slid backward from the high reaction force state, the passive cam body 80 is pushed up by the roller shaft 78 as shown in FIG. 17, and the roller shaft 78 engages with the lowermost engaging recess 82. Along with this, the switching adjusting body 41 moves upward beyond the high reaction force state, the movable lock body 27 engages with the fixed lock body 28, and the lock structure is switched to the locked state. As described above, the movable lock body 27 and the fixed lock body 28 before being engaged are displaced forward and backward. Therefore, as the movable lock body 27 and the fixed lock body 28 start to engage with each other, the shear blade unit 8 is drawn in the clockwise direction around the tilting shaft 18, and the elastic shaft 86 is moved forward by that amount. It is elastically deformed and exerts a backward tilting reaction force.

  As described above, when the movable lock body 27 is engaged with the fixed lock body 28 while the switching adjustment body 41 and the reaction force adjustment body 42 are engaged, the unit frame 12 resists the spring force of the elastic shaft 86. Then tilt forward. Therefore, the user can clearly know that the shear blade unit 8 has been switched to the locked state by visually observing that the shear blade unit 8 is tilted forward. Further, the elastic deformation of the elastic shaft 86 acts on the unit frame 12 in a state where the shear blade unit 8 is locked and held. As a result, the movable lock body 27 and the fixed lock body 28 that engage with each other, and the switching adjustment body 41 and the reaction force adjustment body 42 are brought into close contact with each other by the tilting reaction force, so that the locked state can be maintained in a stable state.

  As described above, in the third embodiment, by sliding the operation tool 29, the reaction force adjusting structure is switched between the standby state, the low reaction force state, and the high reaction force state, and the shear blade unit 8 is shaved. Since the comfort can be adjusted, the usability of the electric razor can be improved as in the first embodiment. Further, in the low reaction force state and the high reaction force state, since the switching adjustment body 41 and the reaction force adjustment body 42 are engaged with each other, the slide knob 77 is slid with the shear blade unit 8 in the neutral position. The tilt reaction force can be increased or decreased by operating.

  FIG. 18 shows another embodiment in which a part of the third embodiment is changed. There, the movable lock body 27 is integrally provided at the base of the elastic shaft 86 of the switching adjustment body 41 so that the movable lock body 27 is engaged with the fixed lock body 28 below the groove of the reaction force adjustment body 42 in the locked state. I made it. Thus, when the movable lock body 27 is provided integrally with the switching adjustment body 41, it is not necessary to separately provide the fixed lock body 28, so that the structure of the unit frame 12 can be simplified. Further, since the engagement center position of the switching adjustment body 41 and the reaction force adjustment body 42 and the movable lock body 27 and the fixed lock body 28 are the same position, the switching from the high reaction force state to the locked state can be performed smoothly.

Example 4 FIGS. 19 to 21 show Example 4 of an electric shaver according to the present invention. The electric razor according to the fourth embodiment is the same as that of the second embodiment. The electric razor according to the first embodiment is configured as a rotary electric razor and the shear blade unit 8 is supported so as to be tiltable in the left-right direction. Different. In the fourth embodiment, the movable lock body 27 that also serves as the switching adjustment body 41 is provided on the unit frame 12 side, and the fixed lock body 28 and the reaction force adjustment body 42 are provided on the main body case 1 side.

  In order to support the shear blade unit 8 so as to be tiltable to the left and right, a unit support 9 is provided on each of the front and rear surfaces of the main body case 1, and the front and rear surfaces of the unit frame 12 are connected by a pair of left and right links 90 connected to the support 9. I support it. Similar to the electric razor of the second embodiment, the shear blade unit 8 is provided with an inner blade 6 that is driven to rotate around the horizontal axis. Inside the unit frame 12, a horizontally placed motor 3 and a motor are arranged. A gear train 60 for transmitting the rotational power 3 to the inner blade 6 is arranged.

  The lock structure is substantially the same as the lock structure described in the first embodiment, but the movable lock body 27 and the operation tool 29 are provided on the unit frame 12 side, and the fixed lock body 28 is provided on the main body case 1 side. The point is different. Similarly, the reaction force adjustment structure is substantially the same as the lock structure described in the first embodiment, but the switching adjustment body 41 is provided on the unit frame 12 side, and the reaction force adjustment body 42 is provided on the body case 1 side. The point to provide is different. On the upper surface of the main body case 1, an entrance 31 for the switching adjustment body 41 is opened (see FIG. 20).

  The reaction force adjusting body 42 is formed of a flat plastic molded product, and connection holes 53 and 54 that engage with the switching adjusting body 41 are formed in the upper and lower penetrating shapes at the center of the plate surface. The reaction force adjusting body 42 includes an upper front slider 44 and a lower rear slider 45. Both sliders 44 and 45 are urged to move toward a neutral position by return springs 46 and 47, respectively. Unlike the slider described in FIG. 1, the front slider 44 and the rear slider 45 in this embodiment are guided and supported by the guide grooves 49 and 50 so as to be slidable in the left and right directions. As shown in FIG. 20, the moderation structure includes a moderation protrusion 37 provided on the operation tool 29 side, and four moderation recesses 38 that are recessed at four positions above and below the knob groove 32.

  The reaction force adjustment structure can be switched between a standby state, a low reaction force state, and a high reaction force state by operating the operating tool 43 (29) up and down. As shown in FIG. 19, since the switching adjustment body 41 in the standby state is separated from the reaction force adjustment body 42, the shear blade unit 8 can freely tilt to the left and right. When the operation tool 43 (29) is pushed down from the standby state, the lower part of the switching adjustment body 41 engages with the connection hole 53 of the front stage slider 44 and switches to the low reaction force state as shown by the solid line in FIG. . When the shear blade unit 8 tilts left and right in the low reaction force state, one of the left and right return springs 46 is compressed and deformed, and therefore, the tilt reaction force corresponding to the elastic deformation amount of the return spring 46 acts on the shear blade unit 8. To do.

  When the operation tool 43 (29) is further pushed down from the low reaction force state, the lower part of the switching adjustment body 41 is connected to the connection holes 53 and 54 of the front slider 44 and the rear slider 45 as shown by an imaginary line in FIG. Engage and switch to high reaction force state. When the shear blade unit 8 tilts left and right in the high reaction force state, the pair of upper and lower return springs 46 and 47 are compressed and deformed by the sliders 44 and 45, so that the shear blade unit 8 is elastically deformed by the return springs 46 and 47. A larger tilting reaction force is applied to match the amount. When the operation tool 43 (29) is further pushed down from the high reaction force state, as shown in FIG. 21, the lower part of the switching adjustment body 41 engages with the fixed lock body 28 and switches to the locked state.

  The lower end of the movable lock body 27 in the locked state is engaged and held by a fixed lock body 28, and the upper and lower middle portions of the movable lock body 27 are engaged and held by a front stage slider 44 and a rear stage slider 45. That is, in a state where the shear blade unit 8 is locked and held, the switching adjustment body 41 and the reaction force adjustment body 42 are engaged, and the shear blade unit 8 is held in position in cooperation with the lock structure. Therefore, even if an external force is applied, the shearing blade unit 8 does not tilt left and right, and the locked state can be maintained stably. As can be understood from this embodiment, the movable lock body 27 also serving as the switching adjustment body 41 can be provided on the unit frame 12 side, and the fixed lock body 28 and the reaction force adjustment body 42 are provided on the main body case 1 side. Can do.

  In addition to the above embodiments, the present invention can also be applied to an electric razor in which the shearing blade unit 8 is floatingly supported so as to be tiltable in all directions. The driving source of the inner blade 6 may be a linear motor. In the electric shaver according to the first embodiment, the switching adjustment body 41 is switched to the standby state, the low reaction force state, the high reaction force state, and the lock state, but this is not necessary. For example, the state in which the switching adjustment body 41 is engaged with the connection hole 53 of the front slider 44 may be referred to as a standby state (low reaction force state), and thereafter switched to a high reaction force state and a locked state. . In the electric shaver according to the first embodiment, the reaction force adjusting body 42 is configured by using the front slider 44 and the rear slider 45 as engaging elements, but either one of the sliders 44 and 45 can be omitted. In that case, the switching adjustment body 41 can be switched between the standby state, the reaction force application state, and the lock state by switching the operation tool 29 (43). Furthermore, in addition to the front stage slider 44 and the rear stage slider 45, a third slider can be provided to diversify the tilt reaction force acting on the shear blade unit 8.

DESCRIPTION OF SYMBOLS 1 Main body case 2 Razor head 6 Inner blade 7 Outer blade 8 Shear blade unit 9 Unit support body 12 Unit frame 27 Movable lock body 28 Fixed lock body 29 Operation tool 41 Switching adjustment body 42 Reaction force adjustment body 43 Operation tool 44 Previous stage slider 45 Rear slider 46/47 Return spring 53/54 Connecting hole

Claims (3)

A shear blade unit (8) provided with an inner blade (6) and an outer blade (7) is supported so as to be tiltable by a unit support (9) provided on the upper part of the main body case (1).
A lock structure that locks the shear blade unit (8) so as not to tilt between the main body case (1) and the shear blade unit (8), and a tilt reaction force when the shear blade unit (8) tilts are adjusted. Reaction force adjustment structure is provided,
The reaction force adjustment structure includes a switching adjustment body (41) provided in one of the main body case (1) and the shear blade unit (8), a reaction force adjustment body (42) provided in the other, and a switching adjustment body ( 41) is provided with an operation tool (43) for switching operation,
In a state in which the switching adjusting body (41) is switched with the operation tool (43), the two adjusting bodies (41, 42) are engaged with each other or frictionally joined to generate a tilt reaction force.
In a state where the shear blade unit (8) is locked and held by the lock structure, the switching adjustment body (41) and the reaction force adjustment body (42) are engaged or frictionally joined to cooperate the shear blade unit (8) with the lock structure. And hold the position ,
The center axis (P2) of the reaction force adjustment body (42) is shifted back and forth with respect to the center axis (P1) of the switching adjustment body (41) and the slide movement line (L1) of the switching adjustment body (41).
The lock structure includes a movable lock body (27), a fixed lock body (28) provided on the central axis (P1) of the switching adjustment body (41), and the movable lock body (27) in a locked state and an unlocked state. It has an operation tool (29) for switching,
In the reaction force application state in which the switching adjustment body (41) and the reaction force adjustment body (42) are engaged or friction-bonded to exert a tilting reaction force, the movable lock body (27) is connected to the fixed lock body (28). The shearing blade unit (8) is engaged against the tilting reaction force and tilted toward the central axis (P1) of the switching adjustment body (41) to be locked so as not to tilt forward and backward. Electric razor. A shear blade unit (8) provided with an inner blade (6) and an outer blade (7) is supported so as to be tiltable by a unit support (9) provided on the upper part of the main body case (1).
A lock structure that locks the shear blade unit (8) so as not to tilt between the main body case (1) and the shear blade unit (8), and a tilt reaction force when the shear blade unit (8) tilts are adjusted. Reaction force adjustment structure is provided,
In the reaction force adjustment structure, the switching adjustment body (41) provided in the main body case (1), the reaction force adjustment body (42) provided in the shear blade unit (8), and the switching adjustment body (41) are switched. It has an operation tool (43),
In a state in which the switching adjusting body (41) is switched with the operation tool (43), the two adjusting bodies (41, 42) are engaged with each other or frictionally joined to generate a tilt reaction force.
In a state where the shear blade unit (8) is locked and held by the lock structure, the switching adjustment body (41) and the reaction force adjustment body (42) are engaged or frictionally joined to cooperate the shear blade unit (8) with the lock structure. And hold the position,
The lock structure includes a movable lock body (27) provided in the main body case (1) that also serves as a switching adjustment body (41), a fixed lock body (28) provided in the shear blade unit (8), and a movable lock body ( 27) is provided with an operating tool (29) for switching up and down;
The reaction force adjustment structure is provided on the main body case (1) and is switched up and down, and the reaction force adjustment body (42) supported by the shear blade unit (8) so as to be slidable back and forth. And
The movable lock body (27) and the switching adjustment body (41) are slid by the operation tool (29, 43), and the reaction force application state in which the switching adjustment body (41) engages the reaction force adjustment body (42). An electric razor characterized in that the movable lock body (27) can be switched to a locked state in which the movable lock body (27) is engaged with the fixed lock body (28). The lock structure includes a rod-shaped movable lock body (27), a fixed lock body (28) composed of a recess that engages with and disengages from the upper end of the movable lock body (27), and an operating tool that slides the movable lock body (27) ( 29)
The reaction force adjusting body (42) of the reaction force adjusting structure is composed of a lower front slider (44) and an upper rear slider (45) which are guided and supported by a shearing blade unit (8) so as to be slidable back and forth. Both sliders (44, 45) are urged to move toward the neutral position by return springs (46, 47),
The front slider (44) and the rear slider (45) are formed with connecting holes (53, 54) that engage with the switching adjustment body (41) in a vertically penetrating manner.
The switching adjustment body (41) includes a low reaction force state in which the switching adjustment body (41) engages with the connection hole (53) of the front slider (44), and the switching adjustment body (41) includes the front slider (44) and the rear stage. It can be switched to a high reaction force state that engages with both connecting holes (53, 54) of the slider (45),
The electric shaver according to claim 2, wherein the movable lock body (27) is engaged with the fixed lock body (28) in the locked state .

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