JP2008126598A - Electromotive mechanical pencil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electromotive mechanical pencil which shrinks and moves back an exciting drive type shape memorizing alloy 14 by exciting a lead holder 4 for holding a lead 3 by moderate force, and extends the exciting drive type shape memorizing alloy 14 when the exciting is stopped and advances the lead holder 4 by a spring 7 and draws out the lead 3 at a fixed amount. <P>SOLUTION: A chuck 9 is provided for allowing the advancing of the lead 3 but stopping the moving back of the lead 3. Further, the lead holder 4 for holding the lead 3 by moderate force is energized forward in a longitudinal direction by a spring 7. This lead holder 4 is moved back by the shrink of the exciting drive type shape memorizing alloy 14. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electric mechanical pencil in which an energization drive type shape memory alloy contracts when energized and a lead is drawn out.

2. Description of the Related Art Conventionally, a mechanical pencil is known in which a shape memory alloy contracts when it is energized to draw out a core. (See Patent Documents 1 and 2)
JP 2005-193583 A JP 2005-254602 A

When the chuck with the tightening ring fitted on the head is advanced by contraction of the shape memory alloy and the core is extended, the pushing force to advance the chuck becomes stronger, and the moving distance to remove the tightening ring from the chuck The battery becomes longer and cannot operate unless the voltage of the dry battery is increased. In addition, the power consumption increases, and the problem that the dry battery has to be replaced frequently arises.
In addition, even when using a ball chuck, in order to expand the chuck and follow the next core, the moving distance of the chuck is also increased and the pushing force to advance the chuck is increased, resulting in high power consumption. It was something that would end up.
An object of the present invention is to provide a replacement core case that solves the above-described problems.

  The present invention provides a chuck that allows the lead to move forward but prevents it from moving backward, and energizes the lead holder in the longitudinal direction by a spring to hold the lead with an appropriate force, thereby energizing it. The first gist is that when the lead holder is moved backward by the memory alloy and the energization is stopped, the lead holder is advanced by the spring and a fixed amount of lead is drawn out.

  A second gist is that a lead guide is slidably incorporated in the base and a lead holder is provided in the lead guide.

  Furthermore, the third gist is that the current-driven shape memory alloy is connected to the core connected to the core guide, and the current-driven shape memory alloy is contracted by energization to retract the core guide.

  Furthermore, the fourth gist is to cause a current to flow through the current-carrying shape memory alloy by manually turning on a switch provided on the shaft cylinder or the like.

  The present invention allows the lead holder to be urged forward by a spring with a slight force and retracts a short distance with a current-driven shape memory alloy by a small amount of force, so that a certain amount of lead can be drawn out, which has the effect of reducing the consumption of dry batteries. It can be played.

  A chuck that allows the lead to move forward but prevents it from moving backward is provided, and the lead holder that holds the lead with an appropriate force is urged forward by a spring, and the lead holder is moved backward by the current-driven shape memory alloy. The machine has a simple structure, smooth operation, and low power consumption.

  Hereinafter, the electric mechanical pencil according to the first embodiment of the present invention will be described with reference to FIGS. 1, 2, 3, 4, 5, 6, and 7. In addition, let the left side of FIG. 1 be the front, and let the right side be the back. First, in FIG. 1, FIG. 2 and FIG. 3, the core guide 2 is built in the base 1 so as to be slidable in the longitudinal direction, and the core 3 is held inside the tip hole of the core guide 2 with an appropriate force. A core holder 4 made of metal is attached. Further, the core 5 is detachably attached to the core guide 2 by screwing, and the rod-like portion 5A of the core 5 is inserted into the connector 6 through the through hole 6A of the connector 6. The base 1 is detachably screwed to the connector 6, and a spring 7 is stretched between the inner stage 5 </ b> B of the core 5 and the front end of the connector 6 with a force of about 20 g to 30 g. Further, as shown in FIG. 3, the distance L between the end portion 5C of the core 5 and the front end of the connector 6 is appropriately separated.

  A fastener 8 is built in the groove 6B of the connector 6 so as to be slidable in the longitudinal direction. Moreover, the recessed part 9A is comprised in the head part of the chuck | zipper 9 which divided the front part by the slot process. Metal balls 10 are respectively disposed in the recesses 9A.

  The chuck 9 is inserted into the fastener 8 and a chuck spring 11 is stretched between the inner stage 8A of the fastener 8 and the outer flange 9B of the chuck 9 with a force of about 10 g. Accordingly, the ball 10 disposed on the head of the chuck 9 is pressed against the tapered surface 8B of the fastener 8 to close the chuck 9, and the lead 3 held by the chuck 9 is allowed to advance but is not allowed to move backward. The Further, the front portion 12A of the lead tank 12 is inserted into the rear cylinder 8C of the fastener 8, and the rubber ring 13 attached to the front concave groove 12B of the lead tank 12 is appropriately attached to the inner surface of the rear tube 8C of the fastener 8. Friction contact with the force of.

  One end of a current-carrying shape memory alloy 14 is fixed to the rod-shaped portion 5A of the core 5. The other end of the energization drive shape memory alloy 14 is fixed to a movable member 15 having a spring contact. A contact spring 16 is stretched between the movable member 15 and the inner stage 6C of the connector 6 with a force of about 50 g. Therefore, the movable member 15 is pressed by the contact spring 16 against the fixed member 17 attached to the connector 6, and the contact 15 </ b> A provided on the movable member 15 and the contact 17 </ b> A provided on the fixed member 17 are in contact with each other.

  Further, a return spring 18 is stretched between the fixing member 17 and the rear outer stage 12C of the core tank 12 with a force of about 500 g, and the front stage 12D of the core tank 12 is attached to the rear inner collar 8D of the fastener 8. Pressed. A cassette 19 is detachably attached to the rear portion of the lead tank 12. The cassette 19 accommodates an AA battery 20 and an eraser 21 and is detachably attached with a knob 22 that covers the eraser 21.

  A shaft cylinder 23 is attached to the connector 6 by press fitting, bonding, screwing or the like. A switch 24 is attached to the recess 23 </ b> A of the shaft cylinder 23. Furthermore, a slidable cover 25 is attached to the shaft cylinder 23, and the switch 24 can be protected. In the writing state, the cover 25 moves rearward, and the inward projection 25A of the cover 25 is engaged with the rear recess 23B of the shaft tube 23.

  In addition, a colored transparent resin clip 26 having light collecting properties is attached to the shaft tube 23, and a lamp 27 is attached to the inside of the clip 26. This lamp 27 is interlocked with the energization drive type shape memory alloy 14 and is turned on when the switch 24 is turned on, and light is emitted from the entire clip 26.

  A concave groove 1A is formed on the outer surface of the base 1, and an O-ring 28 attached to the concave groove 1A makes frictional contact with the front inner surface 23C of the shaft tube 23 with an appropriate force. By rotating the base 1, the base 1 moves forward or backward, and the distance L between the end 5 </ b> C of the core 5 and the front end of the connector 6 changes, and the centering amount is adjusted. That is, it is usually preferable to set the distance L to 1 to 2 mm. However, if the distance L is set to 0.5 mm according to the user's preference, the retraction distance of the core guide 2 becomes 0.5 mm, and the core 3 It becomes the feeding amount.

  When writing is performed from the state of FIGS. 1, 2, and 3 and the lead 3 is consumed, the energization drive shape memory alloy 14 is energized and heated by manually pressing the switch 24 to turn it ON. In addition, the lamp 27 is turned on and the entire clip 26 emits light. When the current-carrying shape memory alloy 14 is heated and contracts, the core 5 is pulled backward, the spring 7 is compressed, and the lead holder 4 slides back on the lead 3.

Then, the end portion 5C of the core 5 is brought into contact with the front end of the connector 6, and the retreat of the core 5 and the core guide 2 is stopped. Then, the lead 3 protrudes from the tip of the lead guide 2 by the length of the lead guide 2 retracted, and the state shown in FIG. 4 is obtained. When the switch 24 is stopped and turned off, the current-carrying shape memory alloy 14 is cooled and extended, and the core guide 2 and the core 5 are urged by the spring 7 to move forward. At this time, the chuck 9 allows the lead 3 to move forward but prevents the lead 3 from moving backward, so the lead 3 moves forward in the chuck 9 together with the lead holder 4 built in the lead guide 2. And it returns to the state of FIG.1 and FIG.3.
If the switch 24 is accidentally kept pressed, excessive heat is applied to the current-carrying shape memory alloy 14 and contracts with a strong force. Then, the core guide 2 and the core 5 are retracted and the end portion 5C of the core 5 is brought into contact with the front end of the connector 6. However, when the current-driven drive type shape memory alloy 14 is further contracted, the contact spring 16 is compressed. Then, the movable member 15 is advanced, the contact 15A and the contact 17A are separated from each other, and the energization is stopped, and the state shown in FIG. 5 is obtained. Therefore, there is no possibility that the current-carrying shape memory alloy 14 will be heated more than necessary, and there is no possibility that the current-carrying shape memory alloy 14 will be damaged or the durability will not be impaired.

  When one lead 3 is consumed and the next lead 3 is fed, the lead tank 12 is advanced by pressing the knob 22, and the fastener 8 connected by the lead tank 12 and the rubber ring 13 is also advanced. To do. When the front end of the fastener 8 comes into contact with the front edge 6D of the concave groove 6B of the connector 6, the advancement of the fastener 8 is stopped. However, the lead tank 12 is further advanced, and the front end of the lead tank 12 presses the rear end of the chuck 9 so that the chuck 9 is expanded to the state shown in FIG. Then, the next core 3 falls into the chuck 9. If the pressing of the knob 22 is stopped in this state, the lead tank 12 is retracted by the return spring 18, but the fastener 8 connected to the rubber ring 13 is also retracted with the chuck 9 expanded, so that the inside of the chuck 9 There is no worry that the next core 3 that has fallen into the back is retracted. The lead 3 shortened by repeating the pressing of the knob 22 several times is discharged from the tip of the lead guide 2 and the next lead 3 is inserted into the lead holder 4 and protrudes from the tip of the lead guide 2.

  Further, when carrying with stopping writing, the cover 25 is slid and moved forward to cover the switch 24 and the inward projection 25A of the cover 25 engages with the front concave portion 23D of the shaft tube 23, and FIG. State.

  When replenishing the lead tank 12 with the lead 3, the cassette 19 is removed from the lead tank 12 and refilled. Also, when the dry battery 20 is replaced, the cassette 19 is removed from the core tank 12 and replaced.

  When the eraser 21 is used, the eraser 21 is used by removing only the knob 22 from the cassette 19 mounted on the core tank 12.

  The electric mechanical pencil according to the second embodiment of the present invention will be described with reference to FIGS. 8, 9, 10, 11, and 12. The left side of FIG. 8 is the front and the right side is the rear. The same members as those in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted. First, in FIGS. 8, 9 and 10, the core guide 2 is built in the base 101 so as to be slidable in the longitudinal direction, and the core 3 is held inside the tip hole of the core guide 2 with an appropriate force. A core holder 4 made of metal is attached. Further, a core 105 is detachably attached to the core guide 2 by screwing, and a rod-like portion 105A provided opposite to the core 105 is provided in the connector 106 through two through holes 106A of the connector 106. Inserted. The base 101 is detachably screwed to the connector 106, and the spring 7 is stretched between the inner stage 105B of the core 105 and the front end of the connector 106 with a force of about 20g to 30g. Further, the end portion 105C of the core 105 and the front end of the connector 106 are separated from each other by about 1 mm to 2 mm.

  A concave portion 109A is formed on the head of the chuck 109, the front portion of which is divided by slitting. A metal ball 10 is disposed in the recess 109A. The chuck 109 is inserted into the connector 106, and the lead tank 112 is press-fitted and fixed to the rear portion 109C of the chuck 109. Further, the chuck spring 11 is stretched between the front inner stage 106E of the connector 106 and the front end of the lead tank 112 with a force of about 10 g. Accordingly, the ball 10 disposed on the head of the chuck 109 is pressed against the tapered surface 106F of the coupler 106 to close the chuck 109, and the lead 3 held by the chuck 109 is allowed to move forward but not retracted. The

  An engaging member 29 is connected to the two rod-like portions 105A of the core 105, and an inner flange 29B is formed on the rear portion 29A of the engaging member 29. The rear portion 29A is located forward in the longitudinal direction from the rear end. A plurality of kerfs 29C are formed toward the rear, and the rear portion 29A is configured to be deflectable. Further, the front portion 112A of the lead tank 112 is inserted into the inner hole 106G of the connector 106, and the tubular portion front portion 112E of the lead tank 112 is formed to have a slightly narrow diameter and an outer collar 112F is formed. Further, a part of the energization drive type shape memory alloy 14 is fixed to either one of the rod-like portions 105 </ b> A of the core 105. The other end of the energization drive shape memory alloy 14 is fixed to a movable member 15 having a spring contact. A contact spring 16 is stretched between the movable member 15 and the inner stage 106C of the coupler 106 with a force of about 50 g. Accordingly, the movable member 15 is pressed by the contact spring 16 against the fixed member 17 attached to the connector 106, and the contact 15A provided on the movable member 15 and the contact 17A provided on the fixed member 17 are in contact with each other.

  A shaft cylinder 123 is attached to the connector 106 by press-fitting, bonding or screwing. The switch 24 is attached to the concave portion 123 </ b> A of the shaft cylinder 123. Furthermore, a slidable cover 25 is attached to the shaft cylinder 123, and the switch 24 can be protected. In the writing state, the cover 25 moves rearward, and the inner protrusion 25A of the cover 25 is engaged with the rear concave portion 123B of the shaft cylinder 123.

  Further, a cassette 119 is detachably attached to the rear portion of the shaft cylinder 123. In the cassette 119, the AAA battery 20 and the eraser 21 are accommodated, and a knob 122 covering the eraser 21 is detachably attached.

  When writing is performed from the states of FIGS. 8, 9 and 10 and the lead 3 is consumed, the energization drive shape memory alloy 14 is energized and heated by pressing the switch 24 to turn it ON. In addition, the lamp 27 is turned on and the entire clip 26 emits light. When the current-carrying shape memory alloy 14 is heated and contracts, the core 105 is pulled backward, the spring 7 is compressed, and the lead holder 4 slides back on the lead 3. At the same time, the inner rod 29B formed at the rear portion of the engaging member 29 gets over the outer rod 112F of the core tank 112 and is engaged.

  Then, the end portion 105C of the core 105 is brought into contact with the front end of the connector 106, and the core 105 and the core guide 2 are stopped. Then, the core 3 protrudes from the tip of the core guide 2 by the length of the retraction of the core guide 2, and the state shown in FIG. 11 is obtained. When the pressing of the switch 24 is stopped and turned OFF, the current-carrying shape memory alloy 14 is cooled and extended, and the core guide 2 and the core 105 are urged by the spring 7 to move forward. In addition, since the inner collar 29B of the engaging member 29 is engaged with the outer collar 112F of the lead tank 112, the lead tank 112 and the chuck 109 together with the core 105 and the lead guide 2 move forward together with the lead 3. At this time, when the chuck 109 moves forward, the ball 10 is separated from the tapered surface 106F of the coupler 106, and the chuck 109 is expanded to be in the state shown in FIG. That is, when one lead 3 is consumed and shortened, the next lead 3 falls in the chuck 109 and comes into contact with the rear end of the shortened lead 3. Accordingly, since the shortened lead 3 can be written while being in contact with the next lead 3, it can be written until it is removed from the lead holder 4. That is, there is almost no core 3 discharged as a residual core, which is very economical and has a positive effect on the environment.

  Then, the front end of the lead tank 112 is brought into contact with the locking step 106H of the connector 106, and the advancement of the chuck 109 and the lead tank 112 is stopped. However, the core guide 2 and the core 105 are further advanced by the spring 7, and the inner flange 29 </ b> B of the engaging member 29 is disengaged from the outer flange 112 </ b> F of the core tank 112. Then, the chuck 109 and the lead tank 112 are retracted by the chuck spring 11 to be in the state shown in FIGS. 8, 9 and 10, and writing is possible.

  If the switch 24 is accidentally kept pressed, excessive heat is applied to the current-carrying shape memory alloy 14 and contracts with a strong force. Then, the core guide 2 and the core 105 are retracted, and the end portion 105C of the core 105 is brought into contact with the front end of the connector 106. However, when the energization drive type shape memory alloy 14 is further contracted, the contact spring 16 is compressed. Thus, the movable member 15 is advanced, the contact 15A and the contact 17A are separated from each other, and energization is stopped. Therefore, there is no possibility that the current-carrying shape memory alloy 14 will be heated more than necessary, and there is no possibility that the current-carrying shape memory alloy 14 will be damaged or the durability will not be impaired.

  Further, when carrying with stopping writing, the cover 25 is slid and moved forward to cover the switch 24 and the inner protrusion 25A of the cover 25 is engaged with the front recess 123D of the shaft cylinder 123. When refilling the lead tank 112 with the lead 3, the cassette 119 is removed from the shaft cylinder 123 and the lead tank 112 is refilled with the lead 3. Also, when the dry battery 20 is replaced, the cassette 119 is removed from the shaft cylinder 123 and replaced.

  When the eraser 21 is used, the eraser 21 is used by removing only the knob 122 from the cassette 119 mounted on the shaft cylinder 123.

  An electric mechanical pencil according to a third embodiment of the present invention will be described with reference to FIGS. 13, 14, 15, and 16. Note that the left side of FIG. 13 is the front and the right side is the rear. The same members as those in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted. First, in FIG. 13 and FIG. 14, a core guide 2 is built in the base 1 so as to be slidable in the longitudinal direction, and a core made of rubber that holds the core 3 with an appropriate force inside the tip hole of the core guide 2. Attach the holder 4. Further, the core 5 is detachably attached to the core guide 2 by screwing, and a rod-like portion 5A provided on the core 5 is inserted into the connector 206 through the through hole 206A of the connector 206. The base 1 is detachably screwed to the connector 206, and the spring 7 is stretched between the inner stage 5B of the core 5 and the front end of the connector 206 with a force of about 20g to 30g. Further, the end portion 5C of the core 5 and the front end of the connector 206 are separated from each other by about 1 mm to 2 mm.

  A recess 209 </ b> A is formed on the head of the chuck 209 whose front portion is divided by slitting. The metal ball 10 is disposed in the recess 209A. The chuck 209 is inserted into the connector 206, and the chuck spring 11 is stretched between the front inner stage 206E of the connector 206 and the outer flange 209B of the chuck 209 with a force of about 10 g. Accordingly, the ball 10 disposed on the head of the chuck 209 is pressed against the tapered surface 206F of the connector 206 to close the chuck 209, and the lead 3 held by the chuck 209 is allowed to move forward but not retracted. The Further, an elastic body 30 formed of rubber or the like is provided in the inner hole 206G of the connector 206, and the outer flange 209B of the chuck 209 is configured to be in frictional contact with the elastic body 30. Note that the outer casing 209B of the chuck 209 and the elastic body 30 are usually separated from each other as appropriate. Further, a core tank 212 that is appropriately separated from the chuck 209 is loosely fitted in the connector 206 and incorporated.

  One end of a current-carrying shape memory alloy 14 is fixed to the rod-shaped portion 5A of the core 5. The other end of the energization drive type shape memory alloy 14 is fixed to a movable member 115 having a spring contact. A contact spring 116 is stretched between the movable member 115 and the outer stage 212G of the core tank 212 with a force of about 50 g. Accordingly, the movable member 115 is pressed against the fixed member 117 attached to the core tank 212 by the contact spring 116, and the contact 115A provided on the movable member 115 and the contact 117A provided on the fixed member 117 are in contact with each other.

  A shaft cylinder 123 is attached to the connector 206 by press-fitting, bonding or screwing. The switch 24 is attached to the concave portion 123 </ b> A of the shaft cylinder 123. Furthermore, a slidable cover 25 is attached to the shaft cylinder 123, and the switch 24 can be protected. In the writing state, the cover 25 moves rearward, and the inner protrusion 25A of the cover 25 is engaged with the rear concave portion 123B of the shaft cylinder 123.

  Further, a cassette 119 is detachably attached to the rear portion of the shaft cylinder 123. In the cassette 119, the AA battery 20 and the eraser 21 are accommodated, and a knob 122 covering the eraser 21 is detachably attached.

  Further, a colored transparent resin clip 26 having a light collecting property is attached to the shaft cylinder 123, and a lamp 27 is attached to the inside of the clip 26. This lamp 27 is interlocked with the energization drive type shape memory alloy 14 and is turned on when the switch 24 is turned on, and light is emitted from the entire clip 26.

  Next, when writing is performed from the state of FIG. 13 and FIG. 14 and the lead 3 is consumed, the energization drive shape memory alloy 14 is energized and heated by pressing the switch 24 to turn it ON. In addition, the lamp 27 is turned on and the entire clip 26 emits light. When the current-carrying shape memory alloy 14 is heated and contracts, the core 5 is pulled backward, the spring 7 is compressed, and the lead holder 4 slides back on the lead 3.

  Then, the end portion 5C of the core 5 is brought into contact with the front end of the connector 206, and the retreat of the core 5 and the core guide 2 is stopped. Then, the core 3 is projected from the tip of the core guide 2 by the length of the retraction of the core guide 2. Further, when the energization drive shape memory alloy 14 contracts, the lead tank 212 is pulled forward together with the movable member 115 and the fixed member 117 to move forward. Then, the front end of the lead tank 212 comes into contact with the rear end of the chuck 209, and the chuck 209 is advanced. When the chuck 209 is advanced, the chuck 209 expands and the outer flange 209B of the chuck 209 is inserted into the elastic body 30 provided on the coupling 206, and the outer flange 209B of the chuck 209 comes into frictional contact with the elastic body 30. It will be in the state of FIG.15 and FIG.16. Therefore, when the lead 3 in use is consumed and shortened, the next lead 3 falls into the chuck 209.

  Next, when the switch 24 is stopped and turned off, the energization drive type shape memory alloy 14 is cooled and extended. As the energization drive type shape memory alloy 14 is extended, the core guide 2 and the core 5 are urged by the spring 7 to advance. At this time, the chuck 209 maintains the expanded state because the outer flange 209B is in frictional contact with the elastic body 30. Accordingly, the lead 3 held by the lead holder 4 also moves forward together with the lead holder 4. When the lead 3 in use is shortened, the next lead 3 follows in a state where it is in contact with the rear end of the lead 3 in use. When the core 5 and the core guide 2 are brought into contact with the base 1, the advancement of the core guide 2 is stopped. Further, when the energization drive type shape memory alloy 14 is extended, the chuck 209 is urged by the chuck spring 11 to move backward, and the outer flange 209B of the chuck 209 is separated from the elastic body 30. Then, the ball 10 provided on the head of the chuck 209 is pressed against the tapered surface 206F of the connector 206, the chuck 209 is closed, and the core 3 is held again. Therefore, since the shortened lead 3 can be written while being in contact with the next lead 3, it can be written until it is removed from the lead holder 4. That is, there are few cores 3 discharged as a residual core, which is very economical and has a positive effect on the environment.

  If the switch 24 is accidentally kept pressed, excessive heat is applied to the current-carrying shape memory alloy 14 and contracts with a strong force. Then, the core guide 2 and the core 5 are retracted and the end portion 5C of the core 5 is brought into contact with the front end of the connector 206. However, when the energization drive type shape memory alloy 14 is further contracted, the contact spring 116 is compressed. Thus, the movable member 115 is advanced, the contact 115A and the contact 117A are separated from each other, and energization is stopped. Therefore, there is no possibility that the current-carrying shape memory alloy 14 will be heated more than necessary, and there is no possibility that the current-carrying shape memory alloy 14 will be damaged or the durability will not be impaired.

  Further, when carrying with stopping writing, the cover 25 is slid and moved forward to cover the switch 24 and the inner protrusion 25A of the cover 25 engages with the front recess 123D of the shaft cylinder 123.

  When replenishing the lead tank 212 with the lead 3, the cassette 119 is removed from the shaft cylinder 123 and the lead tank 212 is filled with the lead 3. Also, when the dry battery 20 is replaced, the cassette 119 is removed from the shaft cylinder 123 and replaced.

  When the eraser 21 is used, the eraser 21 is used by removing only the knob 122 from the cassette 119 mounted on the shaft cylinder 123.

  In all of the above embodiments, the chuck has been explained by dividing the front part by slitting. However, the chuck according to the present invention is formed by combining two pieces of synthetic resin formed by injection molding with each other. Alternatively, the chuck may be formed by combining two metal pieces formed by die casting.

  Further, as the energization drive type shape memory alloy, Ti-Ni type or Ti-Ni-Cu type shape memory alloy can be considered, and biometal BMF75, BMF100, BMF125, BMF150 (manufactured by Toki Corporation) is preferable.

  Furthermore, it is preferable to use a metal or a heat-resistant resin as a member that may come into contact with the current-carrying shape memory alloy.

  Furthermore, in any of the above embodiments, the switch is provided on the shaft cylinder, but the present invention is not limited to the above embodiment, and the switch can be provided on a base, a cassette, a knocking member, or the like. . Further, the cover can be turned or reversed other than the slide.

  Furthermore, in each of the above embodiments, a dry battery is used as a power source. However, the present invention is not limited to a dry battery, and a rechargeable battery can also be used.

  Furthermore, in any of the above-described embodiments, the lead holder is built in the lead guide, but the present invention is not limited to the above-described embodiment, and the lead guide is attached to the base integrally or separately. It is also possible to retract the separated core holder by expansion and contraction of the energization drive type memory alloy.

  There is little shrinkage of the current-driven shape memory alloy, and the core can be fed out by a certain amount with a weak tensile force, so that the consumption of the dry battery can be reduced.

It is sectional drawing which shows the mechanical pencil of Example 1 of this invention. Example 1 It is an expanded sectional view which shows the AA line of FIG. Example 1 FIG. 3 is an enlarged cross-sectional view of a main part showing a tip portion of Example 1. Example 1 It is a principal part expanded sectional view which shows the state which turned on the switch and retracted the core guide. Example 1 It is a principal part expanded sectional view which shows the state which excessive heat applied to the electricity supply drive type shape memory alloy, and the contact 15A and the contact 17A separated. Example 1 It is a principal part expanded sectional view which shows the state which pushed the knob and expanded the chuck | zipper. Example 1 It is sectional drawing which shows the state which covered the switch with the cover in order to carry. Example 1 It is sectional drawing which shows the mechanical pencil of Example 2 of this invention. (Example 2) It is an expanded sectional view which shows the AA line of FIG. (Example 2) It is a principal part expanded sectional view which shows the front-end | tip part of FIG. (Example 2) It is a principal part expanded sectional view which shows the state which turned on the switch and retracted the core guide. (Example 2) It is a principal part expanded sectional view which shows the state which the chuck advanced and expanded with the core guide. (Example 2) It is sectional drawing which shows the mechanical pencil of Example 3 of this invention. (Example 3) It is a principal part expanded sectional view which shows the front-end | tip part of FIG. (Example 3) FIG. 6 is a cross-sectional view showing a state in which the switch is turned on and the lead guide is retracted and the chuck is advanced to expand. (Example 3) It is principal part expanded sectional drawing which shows the front-end | tip part of FIG. (Example 3)

Explanation of symbols

1 Base 2 Core Guide 3 Core 4 Core Holder 5 Core 7 Spring 9 Chuck 14 Current Driven Shape Memory Alloy 23 Shaft 24 Switch 101 Base 105 Core 109 Chuck 123 Shaft 209 Chuck

Claims (4)

  A chuck is provided that allows the lead to advance, but prevents the lead from retreating. The lead holder that holds the lead with an appropriate force is urged forward in the longitudinal direction by a spring and energized to conduct the lead. An electric mechanical pencil characterized in that when the holder is retracted and the energization is stopped, the lead holder is moved forward by a spring and a fixed amount of lead is drawn out.   2. The electric mechanical pencil according to claim 1, wherein a lead guide is slidably incorporated in the base and a lead holder is provided in the lead guide.   3. The electric motor according to claim 2, wherein the current-driven shape memory alloy is connected to a core connected to the core guide, and the current-driven shape memory alloy contracts when energized to retract the core guide. Mechanical pencil.   4. The electric mechanical pencil according to claim 1, wherein a current is passed through the current-carrying shape memory alloy by manually turning on a switch provided on the shaft cylinder or the like.

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