JP5522715B2 - Rotary electric razor - Google Patents

Description

  The present invention relates to a rotary electric razor provided with a roller for raising a beard that is stretched and falling on the skin surface.

  An electric shaver provided with raising means is known, for example, in Patent Documents 1 and 2. In patent document 1, the rotary body for raising is arrange | positioned in parallel adjacent to a rotary inner blade, and the arch-shaped outer blade and the hair | bristle introduction board are each arrange | positioned on the outer surface of both. The outer blade and the hair introduction plate are provided with slit-like hair introduction holes and slit-like hair introduction holes for introducing the raised hairs. The napping rotating body includes spiral napping blades and is driven in a direction opposite to the rotation direction of the rotary inner blade.

  In the electric razor of Patent Document 2, a roller for extending the skin surface is disposed above a cutting blade having a comb-tooth structure. The roller is rotationally driven in a direction away from the cutting blade by a friction roller to stretch the skin surface and raise the hair that has fallen into the skin surface.

  Patent Document 3 discloses a hair removal device provided with a raised rotating body. The brushed rotating body consists of a rubber square frame-like endless ring, and by rotating a part of it with a friction roller, the opposing sides of the ring are rotated outwardly to extend the skin surface. Raise the falling hair.

  In Patent Document 4, a roller is disposed between a pair of front and rear cutting blades, and the roller is pivotally supported by an outer blade holder so as to be freely rotatable. The roller is composed of a round shaft-like rubber-like elastic body and a metal shaft body, which prevents the skin surface from being excessively pressed against the outer blade and prevents the skin surface from being damaged. Yes.

JP 05-317536 A (paragraph number 0007, FIG. 1) JP-A-60-2271 (page 2, lower right column, lines 2 to 9, line 1) Japanese Patent No. 3427134 (paragraph number 0032, FIG. 1) JP 2002-239271 A (paragraph number 0021, FIG. 8)

  In the electric razor of Patent Document 1, a whisker is introduced into the hair introduction hole of the hair introduction plate, the introduced hair is forcibly raised with a rotating body for raising, and then the raised hair is provided on the outer blade. It introduces from the raising introduction hole and cuts with the inner blade. Therefore, there is a possibility that the comb hair falls down on the skin surface before the comb hair raised by the raising body for raising is introduced into the brush introduction hole provided in the outer blade. Moreover, since the outer surface of the raising body for rotation is covered with the arch-shaped hair introduction plate, it is not possible to raise the skin with the raising body for raising.

  In that respect, in the electric razor of Patent Document 2, the skin surface can be extended with a roller that is rotationally driven. However, a blade base that supports a clipper blade-shaped cutting blade and a roller base that supports a roller are supported by a common support shaft so as to be independently swingable. For this reason, the positional relationship between the cutting blade and the roller during beard cutting is not constant, and the cutting blade approaches or moves away from the roller. As a result, even if the skin surface can be extended by the roller, the brushed beard cannot always be cut at the optimum position, and it takes time to cut the beard. For example, the beard cannot be reliably cut unless the razor head is repeatedly slid on the skin surface. Moreover, since it is a necessary condition that the peripheral speed of the roller is larger than the sliding speed of the razor head with respect to the skin surface, it is inevitable that an extra burden is applied to the skin, such as excessive rubbing of the skin surface.

  The endless ring-shaped rotary body for raising according to Patent Document 3 is arranged in a square frame shape so as to surround the hair removal head where the hair removal claw is exposed, and each of the opposing sides rotates outwardly. Driven by. Therefore, when the external load is concentrated locally, such as when only a part of the ring is pressed against the skin surface, or when receiving a drop impact, there is a possibility that the napping rotating body may be separated from the epilation head. There are many problems in putting the raised structure into practical use.

  An object of the present invention is to provide a rotary electric shaver that can bend the beard reliably by extending the skin surface with a roller, and therefore can effectively cut the beard. An object of the present invention is to provide a rotary electric razor that can surely raise a beard while reducing a burden on the skin surface by a roller, and can well prevent bruising of the skin surface after cutting the beard. The object of the present invention is to effectively cut the whisker against the driving load by the rotational inertia force of the cutting blade that is not involved in beard cutting, even when the driving load between the roller exhibiting the raising action and the cutting blade is large. It is to provide a rotary electric razor that can be used in the future.

In the electric razor of the present invention, the cutting unit 7 includes a cutting blade 11 composed of an inner blade 15 that is rotationally driven around a horizontal axis , an outer blade 16 that covers the outer surface of the inner blade 15, and a roller 13 that extends the skin surface. A razor head 3 is provided. The roller 13 includes a roller body 20 and a roller shaft 21 that supports the roller body 20. The roller 13 is rotatable around the horizontal axis about the roller shaft 21. The roller 13 is rotationally driven by a roller driving mechanism so as to rotate in a direction away from the cutting blade 11 on the half surface of the roller body 20 facing the skin surface and in a direction approaching the cutting blade 11 on the other half surface . The peripheral speed of the roller 13 during driving is set to be smaller than the peripheral speed of the inner blade 15.

  The cutting part 7 includes a first cutting blade 11 and a second cutting blade 12 that are disposed adjacent to each other in the front-rear direction. The roller 13 is arranged in a state adjacent to either the first cutting blade 11 or the second cutting blade 12.

  The inner blade 15 of the first cutting blade 11, the inner blade 17 of the second cutting blade 12, and the roller 13 are simultaneously rotationally driven by a single motor 6 provided inside the main body case 1.

  The diameter of the inner blade 17 of the second cutting blade 12 is set larger than the diameter of the inner blade 15 of the first cutting blade 11 and the diameter of the roller 13.

  The roller 13 is disposed between the first cutting blade 11 and the second cutting blade 12. The distance from the roller center of the roller 13 to the rotation center of the inner blade 15 of the first cutting blade 11 is A, and the distance from the roller center of the roller 13 to the rotation center of the inner blade 17 of the second cutting blade 12 is B. , The roller 13 is arranged so as to satisfy A <B.

  The rotation direction of the roller 13 during driving and the rotation direction of the inner blade 15 of the first cutting blade 11 are set in opposite directions.

  The roller width L3 of the roller 13 is set to be equal to or larger than the blade width L1 of the inner blade 15 of the first cutting blade 11 and the blade width L2 of the inner blade 17 of the second cutting blade 12.

  The drive rotation speed of the inner blade 17 of the second cutting blade 12 is set to be smaller than the drive rotation speed of the inner blade 15 of the first cutting blade 11. Accordingly, the peripheral speeds of the inner blades 15 and 17 of the two cutting blades 11 and 12 are approximated.

  A trimmer blade 14 is disposed between the roller 13 and the second cutting blade 12.

  Each of the roller 13 and the trimmer blade 14 is supported so as to freely float up and down, and is advanced and biased upward by the roller spring 24 and the trimmer spring 35. The spring force of the roller spring 24 is set smaller than the spring force of the trimmer spring 35.

  The top of the trimmer blade 14 is positioned at the same height as the tops of the first and second cutting blades 11 and 12. The roller top portion of the roller 13 projects upward from the top portions of the first and second cutting blades 11 and 12.

  In the present invention, the roller 13 provided on the razor head 3 is rotationally driven by a roller driving mechanism, and the skin surface is stretched away from the cutting blade 11, so that the beard that has fallen on the skin surface is reliably raised and cut. It can be cut with the blade 11. In addition, the positional relationship between the cutting blade 11 and the roller 13 at the time of cutting the beard can be kept constant, and the raised beard can be accurately cut with the cutting blade 11. Furthermore, since the peripheral speed of the roller 13 during driving is set to be smaller than the peripheral speed of the inner blade 15, it is possible to prevent the skin surface from being rubbed unnecessarily by the roller 13 when the skin surface is stretched by the roller 13. Therefore, the beard can be raised while reducing the burden on the skin surface by the roller 13, and the skin surface after the beard cutting can be well prevented from being cracked.

  When the first cutting blade 11 and the second cutting blade 12 are provided in the cutting part 7 and the roller 13 is arranged in a state adjacent to either of the cutting blades 11 and 12, both the rollers 13 are in contact with the skin surface. The skin surface can also be received by the cutting blades 11 and 12. In this way, when the skin surface is received by the three cutting blades 11 and 12 and the roller 13, the roller 13 is prevented from being locally pressed against the skin surface, and the load acting on the roller 13 can be reduced. . Further, it is possible to prevent the skin surface from being rubbed unnecessarily by the roller 13.

  When the inner blades 15 and 17 of both the first and second cutting blades 11 and 12 and the roller 13 are simultaneously rotated by a single motor 6, the individual cutting blades 11 and 12 individually perform beard cutting. The cutting resistance can be countered by using the rotational inertia force of the inner blade of the cutting blade on the side not involved in whisker cutting. For example, when cutting a beard growing under the chin, the beard is cut by applying the roller 13 and the first cutting blade 11 to the skin surface. In this case, the rotational resistance of the roller 13 and the cutting resistance of the inner blade 15 of the first cutting blade 11 are driving loads of the motor 6. However, the second cutting blade 12 is separated from the skin surface and rotates idly with the inner blade 17 in sliding contact with the outer blade 18, thereby generating a large rotational inertia force. Therefore, even if a large rotational resistance acts on the roller 13 and the inner cutter 15 of the first cutting blade 11, the rotational inertia force of the inner cutter 17 opposes the previous rotational resistance. Therefore, even when a large amount of whiskers are captured by the first cutting blade 11 and the cutting load increases rapidly, the drive rotational speed of the inner blade 15 decreases momentarily. While preventing by the wheel effect, whiskers can be cut smoothly. In addition, when the 1st cutting blade 11 is separated from the skin surface, the inner blade 15 idles and produces a rotational inertia force, and counters the rotational resistance of the 2nd cutting blade 12.

  When the diameter of the inner blade 17 of the second cutting blade 12 is set larger than the diameter of the inner blade 15 of the first cutting blade 11 and the diameter of the roller 13, the contact area with the skin surface of the second cutting blade 12 can be increased. Since the contact area with the skin surface is large, the beard can be cut effectively in a short time. Moreover, the rotational inertia force of the inner blade 17 demonstrated previously is increased by the part with a large diameter, and the rotational resistance of the 1st cutting blade 11 and the roller 13 can be offset effectively by a flywheel effect.

  When the distance B from the roller center of the roller 13 to the rotation center of the inner blade 17 of the second cutting blade 12 is larger than the distance A from the roller center to the rotation center of the inner blade 15 of the first cutting blade 11, the first cutting is performed. It can prevent that the blade 11 and the 2nd cutting blade 12 contact a skin surface simultaneously. In particular, when performing whisker cutting with the first cutting blade 11 and the roller 13, the second cutting blade 12 can be moved away from the skin surface, and a large rotational inertia force can be generated by the inner blade 17. Therefore, combined with increasing the diameter of the inner blade 17 to increase the rotational inertia force, the rotational resistance of the first cutting blade 11 and the roller 13 is more effectively offset by the flywheel effect of the inner blade 17. it can.

  When the rotation direction of the roller 13 at the time of driving and the rotation direction of the inner blade 15 of the first cutting blade 11 are set in opposite directions, the skin surface is extended while the skin surface is extended away from the first cutting blade 11 by the roller 13. The whisker can be cut with the inner blade 15 that rotates in the direction opposite to the direction in which it is pulled. Therefore, the whisk raised by the roller 13 can be effectively captured by the inner blade 15 and reliably cut. Further, by operating the razor head 3 in the direction in which the first cutting blade 11 follows the roller 13, it is possible to more reliably capture the beard raised by the roller 13.

  When the roller width L3 of the roller 13 is set to be equal to or larger than the blade widths L1 and L2 of the inner blades 15 and 17 of both cutting blades 11 and 12, the skin surface corresponding to the roller width L3 of the roller 13 is stretched. Brush more beards at the same time, and increase the chance of cutting. Further, the beard cutting with the two cutting blades 11 and 12 can be efficiently performed by the amount of the opportunity for cutting the beard.

  The driving speed of the inner blade 17 of the second cutting blade 12 having a large diameter dimension is set to be smaller than the driving speed of the inner blade 15 of the first cutting blade 11, and the inner blades 15 and 17 of both cutting blades 11 and 12 are set. The reason why the peripheral speed is approximated is to reduce the burden on the skin surface by the second cutting blade 12. In the 2nd cutting blade 12 with the large diameter of the inner blade 17, the contact area with respect to a skin surface becomes large compared with the 1st cutting blade 11. FIG. In addition, if the inner blades 15 and 17 are driven at the same rotational speed, the second cutting blade 12 having a large diameter can simultaneously cut a larger amount of whiskers, but the burden on the skin surface increases. However, if the peripheral speeds of the inner blades 15 and 17 of both the cutting blades 11 and 12 are approximated, the amount of whisker cutting by the second cutting blade 12 can be reduced, and the burden on the skin surface can be reduced. Further, since the driving torque of the inner blade 17 can be increased by the amount that suppresses the driving rotation speed, the burden on the skin surface can be reduced by powerfully cutting the beard. There is also an advantage that an increase in the temperature of the inner blade 17 can be suppressed as the drive rotational speed is suppressed.

  When the trimmer blade 14 is disposed between the roller 13 and the second cutting blade 12, the skin surface is received by the trimmer blade 14, the roller 13 is strongly pressed against the skin surface, and the burden on the skin surface can be reduced. . Furthermore, since each of the trimmer blade 14 and the second cutting blade 12 can capture and effectively cut the long hair, the short hair after the cutting is captured by the first cutting blade 11 and the roller 13 and is suitably finished and cut. it can.

  When the roller 13 and the trimmer blade 14 are supported so as to float freely, and the spring force of the roller spring 24 is set to be smaller than the spring force of the trimmer spring 35, the roller 13 is moved downward in advance of the trimmer blade 14 so that the roller 13 It can be prevented from being excessively pressed against the skin surface. Thereby, the roller 13 can be prevented from being strongly pressed against the skin surface, and the load acting on the roller 13 can be reduced. Further, it is possible to reduce the burden on the skin surface by preventing the skin surface from being rubbed strongly by the roller 13.

  When the roller top of the roller 13 protrudes above the tops of the first and second cutting blades 11 and 12 and the trimmer blade 14, the roller 13 is brought into contact with the skin surface in a state preceding the both cutting blades 11 and 12. The beard can be cut with the skin surface always stretched. Therefore, the beard that has fallen on the skin surface can be accurately cut with the two cutting blades 11 and 12, and the shaving operation can be performed efficiently in a short time.

It is a side longitudinal cross-sectional view of an electric razor. It is a front view of an electric razor. It is a vertical front view which shows the support and drive structure of a roller. It is a vertical front view which shows the support and drive structure of a trimmer blade. It is a conceptual diagram which shows the drive structure of both the cutting blades and a roller. It is a top view of both cutting blades and a roller. It is explanatory drawing which shows the usage example of an electric shaver. It is a side longitudinal cross-sectional view of the electric razor which concerns on another Example. It is a side longitudinal cross-sectional view of the electric razor which concerns on another Example.

(Example) FIG. 1 thru | or FIG. 7 shows the Example of the rotary electric shaver which concerns on this invention. In FIG. 2, the rotary electric shaver includes a main body case 1 and an operation unit assembled to the main body case 1. A switch button 2 for starting the motor is provided on the front surface of the main body case 1, and a shaving blade unit (not shown) is provided on the upper back surface. The operation unit is composed of an electrical component unit on the lower half side and a razor head 3 provided on the upper portion of the electrical component unit. The electrical component unit includes a circuit board and a secondary battery 4. On the circuit board, a switch unit that is turned on / off by the previous switch button 2, electronic components that constitute a control circuit, LEDs for a display unit, and the like are mounted.

  The razor head 3 includes a head frame 5, a motor 6 fixed to the lower portion of the razor head, a cutting portion 7 disposed on the upper portion of the razor head 3, a drive structure for transmitting the power of the motor 6 to the cutting portion 7, and a head. The outer blade holder 8 is detachably attached to the frame 5. The razor head 3 is supported by the main body case 1 so that it can float up and down, and can be tilted back and forth and tilted left and right. The electrical component unit including the motor 6 and the circuit board is sealed with a molding packing provided between the razor head 3 and the main body case 1.

  The cutting part 7 is arranged between the first cutting blade (cutting blade) 11, the second cutting blade (cutting blade) 12, and the two cutting blades 11, 12 which are arranged adjacent to the razor head 3 in front of and behind. The roller 13 and the trimmer blade 14 are configured. The roller 13 that extends the skin surface is disposed on the back of the first cutting blade 11, and the trimmer blade 14 is disposed between the roller and the second cutting blade. The trimmer blade 14 mainly cuts long hairs and comb hairs. Moreover, the 1st cutting blade 11 and the 2nd cutting blade 12 cut | disconnect mainly short hair, respectively.

  As shown in FIG. 1, the first cutting blade 11 and the second cutting blade 12 are respectively an inner blade 15, 17 that is rotationally driven around the horizontal axis, and an outer blade that individually covers the outer surfaces of both inner blades 15, 17. It consists of 16.18. Both inner blades 15 and 17 are configured by spirally arranging ten small blades on the peripheral surface of a round shaft-shaped blade holder. The inner blade driving structure to be described later has a direction indicated by an arrow M in FIG. Is driven to rotate. Both outer blades 16 and 18 are mesh blades formed by electroforming, respectively, and are held in an arch shape by the outer blade holder 8 described above.

  In FIG. 3, the roller 13 includes a roller body 20 made of rubber or elastomer and a roller shaft 21 that supports the roller body 20, and the left and right ends of the roller shaft 21 are pivotally supported by a reverse-portion-shaped roller support frame 22. It is. A passive pulley 23 that inherits the rotational power of the roller drive structure is fixed to one end of the roller shaft 21. The entire roller 13 is supported by the head frame 5 so as to freely float up and down, and is urged upward by a roller spring 24. Specifically, the slide protrusions 25 provided on both side ends of the roller support frame 22 are guided by the guide grooves 26 provided on the left and right guide frames on the upper surface of the head frame 5 so as to be slidable up and down. Further, a roller spring 24 made of a compression coil spring is disposed between the two left and right portions of the lower surface of the roller support frame 22 and the upper surface of the head frame 5. The roller 13 may be formed of metal or plastic.

  In FIG. 4, the trimmer blade 14 includes an inner blade 30 and an outer blade 31 each made of a slit blade having a semi-cylindrical cross section, an inner blade frame 32 that supports the inner blade 30, and a pair of left and right blade receivers that support the outer blade 31. A piece 33 and an inner blade spring 34 made of a leaf spring that urges the inner blade 30 in close contact with the outer blade 31 are formed. The trimmer blade 14 is supported by the outer blade holder 8 so as to freely float up and down, and is urged upward by a trimmer spring 35. Specifically, the slide claw 37 provided on the outer surface of the blade receiving piece 33 is guided by a guide groove 38 provided on the inner surface of the side wall of the outer blade holder 8 so as to be slidable up and down. Further, a trimmer spring 35 made of a compression coil spring is disposed between the double-blade receiving piece 33 and the inner frame 39 of the outer blade holder 8. The spring force of the roller spring 24 described above is set smaller than the spring force of the trimmer spring 35.

  A drive structure for transmitting the rotational power of the motor 6 to the cutting part 7 is shown in FIG. The drive structure is configured by using one motor 6 as a drive source, two inner blade drive structures for driving the inner blades 15 and 17 of the first cutting blade 11 and the second cutting blade 12, and the roller 13. And a trimmer drive structure for reciprocatingly driving the inner blade 30 of the trimmer blade 14.

  The inner blade drive structure has an output gear 41 and a face gear 42 that convert rotational power around the vertical axis of the motor 6 into rotational power around the left and right axes, and the rotational power of the face gear 42 is fixed to the inner blade shafts 15a and 17a. It comprises gear trains 45 and 46 that are transmitted to the passive gears 43 and 44. The inner blade 15 of the first cutting blade 11 and the inner blade 17 of the second cutting blade 12 that have received motor power are rotationally driven in the same direction as indicated by arrows M, respectively.

  The roller driving structure includes a gear train 49 branched from the gear train 45 for the first cutting blade 11, a final gear 50 of the gear train 49, and a winding transmission structure provided between the roller shaft 21. To do. As described above, the roller 13 is supported by the head frame 5 so as to freely float up and down, and in order to absorb the up and down float operation of the roller 13, rotational power is transmitted to the roller 13 through the winding transmission structure. ing. Thus, by using the winding transmission as a transmission medium, the roller 13 can be slipped and the skin surface can be protected when an excessive load is applied.

  The winding transmission structure includes a driving pulley 51 that rotates together with the final gear 50, a passive pulley 23 fixed to the roller shaft 21, a belt 52 wound around both pulleys 51, 23, and circumscribed on one side of the belt 52. The tension pulley 53 is used. The rotation direction of the roller 13 that is rotationally driven via the winding transmission structure is set in a direction away from the first cutting blade 11 and opposite to the rotation direction of the inner blade 15, and the peripheral speed is the inner speed. Set smaller than the peripheral speed of the blades 15 and 17. Specifically, when the peripheral speed of the small blade tip of the inner blade 15 of the first cutting blade 11 is 1.5 m / sec, the peripheral speed of the roller 13 is 0.5 m / sec. The peripheral speed of the roller 13 is preferably set faster than the moving speed (5 to 20 cm / s) when the razor head 3 is moved along the skin surface.

  When the roller 13 floats up and down, the tension pulley 53 swings to absorb the slack of the belt 52. Therefore, the rotational power can be transmitted to the roller 13 regardless of the change in the vertical position of the roller 13. Further, when an excessive load is applied to the roller 13, for example, the passive pulley 23 and the belt 52 slip to suppress power transmission, and the skin surface pulling force by the roller 13 can be reduced. Further, when the razor head 3 is strongly pressed against the skin surface, the roller 13 sinks and the pressing force on the skin surface is reduced, and the burden on the skin surface can be reduced.

  As shown in FIGS. 4 and 5, the trimmer drive structure includes an eccentric cam 56 that meshes with the output gear 41, a vibrator 57 that is driven back and forth by the eccentric cam 56, and a drive that projects from the upper surface of the vibrator 57. The shaft 58 and the passive portion 59 that is provided on the inner blade frame 32 and inherits the operation of the drive shaft 58 are configured. The eccentric cam 56 is composed of a gear that meshes with the output gear 41 and an eccentric pin that protrudes at an eccentric position on the upper surface thereof. The reciprocating motion of the vibrator 57 is also transmitted to the shaving blade unit disposed on the back surface of the main body case 1.

  As described above, the trimmer blade 14 mainly cuts long hairs and comb hairs. Moreover, the 1st cutting blade 11 and the 2nd cutting blade 12 cut | disconnect mainly short hair, respectively. The positions and dimensional relationships of the first and second cutting blades 11 and 12, the roller 13, and the trimmer blade 14 are set as follows. The diameter of the inner blade 17 of the second cutting blade 12 is set larger than the diameter of the inner blade 15 of the first cutting blade 11 and the diameter of the roller 13.

  When the diameter of the inner cutter 17 of the second cutting blade 12 is set larger than the others, the peripheral speed of the inner cutter 17 of the second cutting blade 12 is larger than the other when the rotational speeds of both inner cutters 15 and 17 are the same. Therefore, there is a risk of placing a heavy burden on the skin surface. In order to eliminate such a situation, the driving rotational speed of the inner blade 17 of the second cutting blade 12 is set to be smaller than the driving rotational speed of the inner blade 15 of the first cutting blade 11, The peripheral speeds of the blades 15 and 17 are set to be approximate or the same. For this purpose, the reduction ratio of the gear train 46 of the second cutting blade 12 is made larger than the reduction ratio of the gear train 45 of the first cutting blade 11 so that the peripheral speeds of the inner blades 15 and 17 are the same. Specifically, the peripheral speed of the tip of the small blade of the inner blade 17 of the second cutting blade 12 was 1.5 m / sec.

  As shown in FIG. 1, the distance from the roller center of the roller 13 to the rotation center of the inner blade 15 of the first cutting blade 11 is A, and from the roller center of the roller 13 to the inner blade 17 of the second cutting blade 12. When the distance to the rotation center is B, the roller 13 is arranged so as to satisfy A <B. Thus, by making the distance B larger than the distance A, when cutting the short beard with the first cutting blade 11 while extending the skin surface with the roller 13, the second cutting blade 12 is prevented from contacting the skin surface. Can do. At this time, the inner blade 17 of the second cutting blade 12 in the no-load state has a large diameter dimension, and exhibits a flywheel effect with its own rotational inertia force. Therefore, the rotational resistance of the first cutting blade 11 and the roller 13 can be effectively offset by the flywheel effect of the inner blade 17.

  At the time of shaving, the beard is cut while long hair shaving, rough shaving and finishing shaving are used alone or in combination. At the time of shaving long hair, long hair and comb hair are mainly cut by the trimmer blade 14. During rough shaving, the second cutting blade 12 having a large contact area with the skin surface is used to cut short hairs, or the trimmer blade 14 is used to cut long hairs, and the second cutting blade 12 is used to cut short hairs. To do. Furthermore, at the time of finishing shaving, the short hair is cut by the first cutting blade 11 or the first cutting blade 11 having a larger contact pressure to the skin surface than the second cutting blade 12, or by the first cutting blade 11 and the second cutting blade 12. Cut in parallel. By providing a distance difference between the distance B and the distance A, it is possible to accurately select various beard cutting forms as described above.

  As shown in FIG. 7, when the razor head 3 is moved in the direction of arrow P to finish shave the jaws or the like, the rotational resistance of the roller 13 in contact with the skin surface and the inside of the first cutting blade 11 The cutting resistance of the blade 15 becomes a load with respect to the driving force of the motor 6. In this state of use, the second cutting blade 12 is away from the skin surface, and the inner blade 17 rotates idly while being in sliding contact with the outer blade 18 to generate a rotational inertia force. Moreover, since the diameter dimension of the inner blade 17 is larger than the diameter of the inner blade 15 of the first cutting blade 11, a larger rotational inertia force is generated. Therefore, even when a large amount of whiskers are captured by the first cutting blade 11 and the cutting load increases rapidly, the drive wheel speed of the inner blade 15 decreases momentarily. Preventing by the effect, the whisker cutting can be continued smoothly.

  As described above, the rotation maintaining action by the flywheel effect of the inner blade 17 allows the inner blades 15 and 17 of both cutting blades 11 and 12 and the roller 13 to be simultaneously rotated by one motor 6 provided in the main body case 1. It can be realized by driving. In addition, when performing the whisker cutting with the second cutting blade 12, the rotational inertia force of the inner blade 15 of the first cutting blade 11 that is away from the skin surface is used to reduce the cutting resistance of the inner blade 17 of the second cutting blade 12. On the other hand, it is possible to similarly prevent a momentary decrease in the driving rotational speed.

  In the rotary electric razor, when the razor head 3 moves in the direction of the arrow P, the rotation direction of the inner blades 15 and 17 is set to be opposite to the arrow P. This is because when the razor head 3 is moved in the direction of arrow P in FIG. 7, the whiskers captured in the blade holes of the outer blades 16 and 18 are pressed against the inner edge of the blade hole on the opposite side to the arrow P direction, This is because the whiskers can be immediately cut with the inner blades 15 and 17 and the outer blades 16 and 18 in this state. When the rotation direction of the inner blades 15 and 17 is opposite, the whisker pressed against the inner edge of the blade hole on the opposite side to the arrow P direction is used to The hair must be cut only after moving to the inner edge.

  As shown in FIG. 1, the top of the trimmer blade 14 is positioned at the same height as the top of the first and second cutting blades 11 and 12. On the other hand, the roller top of the roller 13 protrudes upward from the top of the first and second cutting blades 11 and 12 by an amount indicated by the dimension H. In this way, by projecting the roller 13 upward from the tops of the two cutting blades 11 and 12, the roller 13 can be brought into close contact with the skin surface during finishing shaving and the skin surface can be extended. Further, since the roller 13 stretches the skin surface while pulling it in the direction opposite to the rotation direction of the inner blade 15, it is possible to forcibly raise a beard that has fallen on the skin surface.

  As shown in FIG. 6, when the blade width of the inner blade 15 of the first cutting blade 11 is L1, the blade width of the inner blade 17 of the second cutting blade 12 is L2, and the roller width of the roller 13 is L3, The relationship between the width dimensions of the inner cutters 15 and 17 and the roller 13 is set so as to satisfy the inequality (L1 = L2) <L3. As described above, when the roller width L3 of the roller 13 is set larger than the blade widths L1 and L2 of the inner blades 15 and 17, the skin surface wider than the cutting region of the first cutting blade 11 and the second cutting blade 12 is rolled onto the roller. It is possible to effectively cut the beard by raising the beard that has been pulled and stretched at 13 and falling down on the skin surface. The roller width L3 of the roller 13 only needs to satisfy the equation (L1 = L2 = L3), and it is only necessary to satisfy at least (L1 <L3) regardless of the relationship between the blade width L1 and the blade width L2.

  As described above, in the electric shaver of the present invention, the rotation direction of the roller 13 during driving is opposite to the rotation direction of the inner blade 15 of the first cutting blade 11. Therefore, at the time of cutting the beard, the surface of the skin can be extended away from the first cutting blade 11 by the roller 13, and the beard that has fallen down on the skin surface can be raised and the first cutting blade 11 can be suitably cut with a manifold. At this time, since the inner blade 15 rotates in the opposite direction to the roller 13, it is possible to effectively capture the brushed whiskers and cut them reliably. In addition, since the peripheral speed of the roller 13 that is in close contact with the skin surface is set to be smaller than the peripheral speed of the inner blades 15, 17, the burden on the skin surface by the roller 13 can be reduced. It can be prevented from rubbing by rubbing with.

  FIG. 8 shows another embodiment of the electric razor according to the present invention. There, the first cutting blade 11 and the second cutting blade 12 are arranged before and after the upper part of the razor head 3, and the trimmer blade 14 is arranged between both the cutting blades 11 and 12. Further, a roller 13 was disposed on the front side of the first cutting blade 11. The rotation direction of the roller 13 at the time of driving was set to the same direction as the inner blade 15 of the first cutting blade 11. Further, the heights of the tops of the roller 13, the first cutting blade 11, the trimmer blade 14, and the second cutting blade 12 are gradually lowered from the front portion to the rear portion of the razor head 3, so that the first cutting blade 11. And the second cutting blade 12 are prevented from contacting the skin surface at the same time. Since others are the same as the previous embodiment, the same reference numerals are assigned to the same members, and descriptions thereof are omitted. The same applies to the following embodiments.

  As described above, when the roller 13 is disposed on the front side of the first cutting blade 11, the rotation direction of the roller 13 is the same as the rotation direction of the inner blade 15. However, since the inner blade 15 does not directly touch the skin surface, the roller 13 stretches the skin surface away from the first cutting blade 11 and removes the beard that has fallen into the skin surface, as in the previous embodiment. Can be raised forcibly. When cutting the whiskers while moving the razor head 3 in the direction of the arrow P, the roller 13 is driven to rotate in the same direction as the moving direction of the razor head 3, so that the roller 13 stretches the skin surface. At the same time, the razor head 3 is pushed in the direction of arrow P. Therefore, by arranging the roller 13 on the front side of the first cutting blade 11, the movement operation of the razor head 3 operated in the arrow P direction can be assisted by the roller 13.

  FIGS. 9A and 9B show still another embodiment of the electric shaver according to the present invention. In FIG. 9A, the cutting unit 7 is configured by the first cutting blade 11 and the roller 13, and the roller 13 is disposed on the rear side of the first cutting blade 11. The rotation direction of the roller 13 at the time of driving was opposite to the inner blade 15 of the first cutting blade 11. Also in this embodiment, the roller top of the roller 13 protrudes upward from the top of the first cutting blade 11. Therefore, also in the electric razor in this embodiment, it is possible to forcibly raise the beard that has fallen on the skin surface by extending the skin surface with the roller 13.

  In FIG. 9B, the cutting unit 7 is configured by the first cutting blade 11, the second cutting blade 12, and the roller 13, and the roller 13 is disposed on the rear side of the second cutting blade 12. The diameter of the inner blade 15 of the first cutting blade 11 and the diameter of the inner blade 17 of the second cutting blade 12 are the same, and the rotation direction of the roller 13 during driving is the inner blades 15 and 17 of both cutting blades 11 and 12. The direction of rotation was reversed. In this embodiment, the top positions of the two cutting blades 11 and 12 are set to the same height, and the roller tops of the rollers 13 are projected upward from the tops of the two cutting blades 11 and 12.

  During use, the skin surface is pulled by the roller 13 in the direction opposite to the rotation direction of the inner blades 15 and 17 of the first cutting blade 11 and the second cutting blade 12, and the beard collapsed on the skin surface is forcibly raised. it can. Further, by raising the skin surface of the razor head 3 against the skin surface, the skin surface between the second cutting blade 12 and the roller 13 or the skin surface between the first cutting blade 11 and the roller 13 is pulled to raise can do.

  In the above embodiment, each of the inner blades 15 and 17 and the roller 13 is driven simultaneously by one motor 6, but this is not necessary, and each of the inner blades 15 and 17 and the roller 13 is dedicated to each. It is possible to drive with a two-system inner blade drive structure and a roller drive structure using a motor as a drive source. Alternatively, the inner blades 15 and 17 can be simultaneously driven by one motor 6 and only the roller 13 can be driven by a dedicated motor.

  In the above-described embodiment, the trimmer blade 14 is disposed between the roller 13 and the second cutting blade 12, but this is not necessary and the trimmer blade 14 can be omitted. The razor head 3 does not need to be supported by the main body case 1 so that it can float up and down, tilt back and forth, and tilt right and left, and may be an electric razor on which the razor head 3 is fixedly supported by the main body case 1.

DESCRIPTION OF SYMBOLS 3 Razor head 7 Cutting part 11 First cutting blade 12 Second cutting blade 13 Roller 15 Inner blade 16 of the first cutting blade 17 Outer blade of the first cutting blade 17 Inner blade 18 of the second cutting blade 18 Outer blade of the second cutting blade

Claims (11)

A cutting portion including a cutting blade (11) composed of an inner blade (15) driven to rotate about the horizontal axis and an outer blade (16) covering the outer surface of the inner blade (15), and a roller (13) for extending the skin surface (7) is provided on the razor head (3),
The roller (13) includes a roller body (20) and a roller shaft (21) that supports the roller body (20),
The roller (13) is rotatable around the horizontal axis around the roller axis (21),
The roller (13) is driven so as to rotate in a direction away from the cutting blade (11) on the half surface of the roller body (20) facing the skin surface and in a direction approaching the cutting blade (11) on the other half surface. It is rotationally driven by the mechanism ,
The rotary electric shaver according to feature that the peripheral speed of the roller (13), is set smaller than the peripheral speed of the inner cutter (15) at the time of driving. The cutting part (7) is configured to include a first cutting blade (11) and a second cutting blade (12) arranged adjacent to each other in the front-rear direction,
The rotary electric shaver according to claim 1, wherein the roller (13) is disposed adjacent to either the first cutting blade (11) or the second cutting blade (12).   One inner blade (15) of the first cutting blade (11), an inner blade (17) of the second cutting blade (12), and a roller (13) provided in the body case (1). The rotary electric shaver according to claim 2, wherein the rotary shaver is simultaneously driven to rotate by a motor (6).   The diameter of the inner blade (17) of the second cutting blade (12) is set to be larger than the diameter of the inner blade (15) of the first cutting blade (11) and the diameter of the roller (13). The rotary electric shaver according to any one of 3 above. A roller (13) is disposed between the first cutting blade (11) and the second cutting blade (12);
The distance from the roller center of the roller (13) to the rotation center of the inner blade (15) of the first cutting blade (11) is (A), and the second cutting blade (12) from the roller center of the roller (13). The rotary according to claim 2, 3 or 4, wherein the roller (13) is arranged so as to satisfy (A <B), where (B) is a distance to the rotation center of the inner blade (17). Electric razor of the formula. And rotational direction of the roller (13) at the time of driving, according to any one of the first cutting blade (11) of the inner cutter (15) according to claim 2 to 5, and the rotational direction is set opposite to each other of Rotary electric razor. The roller width (L3) of the roller (13) is such that the blade width (L1) of the inner blade (15) of the first cutting blade (11) and the blade width of the inner blade (17) of the second cutting blade (12) ( The rotary electric shaver according to any one of claims 2 to 6 , which is set equal to or larger than L2). The driving rotational speed of the inner blade (17) of the second cutting blade (12) is set smaller than the driving rotational speed of the inner blade (15) of the first cutting blade (11), and both cutting blades (11, 12). The rotary electric shaver according to claim 4, wherein the peripheral speed of the inner blade (15, 17) is approximated.   The rotary electric shaver according to any one of claims 2 to 8, wherein a trimmer blade (14) is disposed between the roller (13) and the second cutting blade (12). Each of the roller (13) and the trimmer blade (14) is supported so as to freely float up and down, and is advanced and biased upward by the roller spring (24) and the trimmer spring (35).
The rotary electric shaver according to claim 9, wherein the spring force of the roller spring (24) is set smaller than the spring force of the trimmer spring (35). The top of the trimmer blade (14) is positioned at the same height as the top of the first and second cutting blades (11, 12);
The rotary electric shaver according to any one of claims 9 to 10 , wherein the roller top portion of the roller (13) protrudes upward from the top portions of the first and second cutting blades (11, 12).

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