JP3680433B2 - Multi-core writing instrument - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention has a plurality of writing bodies including at least one sharp pencil in the shaft body, and the writing bodies are urged rearward by an elastic member, but are attached to the rear end of the writing body. The present invention relates to a multi-core writing instrument in which the pressing member is advanced so that the writing body protrudes from the shaft body.
[0002]
[Prior art]
  Japanese Utility Model Publication No. 56-35354 and Japanese Utility Model Publication No. 56-16312 are known as multi-core writing instruments in which one of the writing bodies is a sharp pencil.
  The utility model registration request of the former Japanese Utility Model Publication No. 56-35354 includes the following: “In the shaft cylinder 1, the sharp pencil mechanism 4 and the ball pen mechanism 6 are slidably opposed to each other. The shaft cylinder 1 has the longitudinal guide grooves 2 and 3 facing each other at the neck, and the neck 8 of the shaft cylinder 1 is slid with a pusher 8 having two push legs 801 and 802 projecting from each other. The sharp pencil mechanism 4 includes a chuck 401 provided at the tip of the core case 405, a tightening ring 402 to which the chuck 401 is fitted or unloaded, and an elastic machine 404 that reciprocally moves the chuck 401. The ball pen mechanism 6 is constructed by providing a ball ball 602 at the distal end of the ink tube 601 and the finger depressor 7 is attached to the proximal end. , 7 are arranged opposite to each other on the side of the presser 8, Protrusions 501 and 701 for engaging the push legs 801 and 802 and projecting and holding the mechanisms 4 and 6 from the shaft cylinder 1 are provided near the pusher 8, and in the middle of the opposing surfaces of the pushers 5 and 7 The protrusions 501 and 701 and the push legs 801 and 802 are provided with overhanging protrusions 502 and 702 so that the opposite side of the acupressure elements 5 and 7 faces the longitudinal guide grooves 2 and 3. However, both the mechanisms 4 and 6 are passed through the middle tool 9 provided in the shaft tube 1, and the bullet machines 10 and 11 are interposed between the middle tool 9 and the acupressure elements 5 and 7, respectively. The writing instrument is characterized in that it is configured so that the shafts 4 and 6 are always retracted into the shaft cylinder 1. "As a description of operating the sharp pencil mechanism 4, the detailed description includes" At the neck end of the rear shaft 102 of the shaft cylinder 1, the leading end 40 of the writing core a of the sharp pencil mechanism 4 is provided. The pusher 8 for adjusting the protruding length from the slidably fit is slidably fitted, but the pusher fracture cross-section is formed into a U-shape, and the two push legs 801 and 802 are provided so as to protrude. Are pushed by both of the push legs 801 and 802 through the acupressure element 5 and the reciprocating slide 404, chuck 401, tightening ring 402, etc. of the sharp pencil mechanism 4 are reciprocated. -Like the pencil, the writing core a is projected from the tip 403 and the length of the projection is adjusted. "(Publication 3rd column, lines 16 to 26).
[0003]
  The utility model registration claim of the latter Japanese Utility Model Publication No. 56-16312 includes a lower shaft case 1 having a tip opening 29; two guide grooves 10 extending in the axial direction and facing each other in diameter. 10 'and a guide sleeve 9 fixed to the rear end opening of the lower shaft case 1; the lower shaft with the writing front end facing the front end opening 29 of the lower shaft case 1; Knock-type sharp pencil element 3 and ball pen having sliders 7, 7 'arranged in the case and each guided at the rear end thereof by a corresponding one of the guide grooves 10, 10' Element 3 '; surrounds the guide sleeve 9 so that it can be pivoted all around the guide sleeve 9 in the left-right direction and can move in a certain section in the axial direction with respect to the guide sleeve 9; Writing both writing elements 3, 3 'alternately every 180 ° rotation A curved case in which a slide inclined surface 13, a notch engaging portion 14 and a flat portion 15 are formed on the lower end surface to be engaged with the sliders 7 and 7 'under a spring pressure so as to be advanced to a position or retracted to a storage position. The guide sleeve 9 has a shaft head 16 at the top thereof, and a cam 18 is engaged with the outer peripheral surface of the outer shaft, and the cam 18 is engaged with the upper end of the curved casing 8. The cam 18 and the fan stopper 12 are disengaged from each other when the pencil element 3 protrudes from the tip opening 29 of the lower shaft case 1. The reciprocating transition in the axial direction of the bent casing 8 with respect to the guide sleeve 9 is possible, and the transition is in the writing position via the slider 7 engaged with the notch engaging portion. 3 is transmitted to When the lead core is unwound by the hook operation and the ball pen element 3 'protrudes from the tip opening 29 of the lower shaft case 1, it engages with each other and the bent casing 8 Writing instrument characterized by being comprised so that transition to an axial direction may be latched. Is described.
[0004]
[Problems to be solved by the invention]
  However, in any of the above prior arts, a member for operating a mechanism for feeding the core of the sharp pencil (the acupressure element 5 in the former and the slider 7 in the latter) causes the sharp pencil to protrude from the shaft body. It is also an engaging member that prevents the immersion of the case. Therefore, in the writing instrument having such a configuration, almost all the load applied to the core, which is generated during writing, is applied to the engaging portion. And when the load by writing is applied to an engaging part, it will be in the same state as when the core feeding mechanism is pressed. That is, the chuck expands and the core is immersed.
  Here, in order to prevent the core from immersing, there is also a thing that the shape of the core biting portion of the chuck is formed in a sawtooth shape and bites the core, but its effect is small, and when the biting force is large Sometimes the core was broken.
  In addition, a spring with a large resilience (for opening and closing the chuck and feeding the core) is used to prevent the core feeding mechanism from operating easily. Not only makes the pressing operation difficult, but also increases the gripping force of the lead, which also has a risk of breaking the lead.
[0005]
[Means for Solving the Problems]
  The present invention has been made to solve the above problems, and has a plurality of writing bodies including at least one sharp pencil in the shaft body, and the writing bodies are urged rearward by a resilient member. However, in the multi-core writing instrument which is made to project the writing body from the shaft body by advancing the pressing member attached to the rear end of the writing body,A slit in the shaft body Forming and slidably disposing the pressing member in the slit,The sharp pencil has an outer member connected to the pressing member, a tip member fixed to the tip of the outer member, and a lead core feeding mechanism slidably arranged inside the outer member and the tip member. In addition, the gist is that a knock member for operating the lead core feeding mechanism is arranged in the pressing member.
[0006]
[Action]
  The outer member of the sharp pencil is engaged and fixed to the shaft main body, and the lead core feeding mechanism is operated by a knock member that operates independently from the outer shaft.
[0007]
【Example】
  An example will be described with reference to FIGS. A multi-core writing instrument in which a sharp pencil and two ball pens are slidably arranged. Instead of a combination of one type of sharp pencil and a ball pen, a plurality of types of sharp pencils may be used. In addition, a combination of two or more types of sharp pencils and colored ball pens may be used. There may be. Reference numeral 1 denotes a shaft main body, and the shaft main body 1 includes a front shaft 2 and a rear shaft 3. Further, in this example, the front shaft 2 is constituted by a screwed structure of the tip member 4 and the middle shaft 5, but may be a means such as press-fitting or fitting, and is formed integrally. Also good.
[0008]
  The rear shaft 3 is formed with three slits 6 in the longitudinal direction. In this example, three slits 6 are formed. However, this is because there are three sharp pencils and two ball pens, and the slits are formed according to the number of the cursive letters. The number also changes. The slit 6 is formed up to one end of the rear shaft 3, and sliding grooves 7 are formed on both sides of the slit 6 in the longitudinal direction. However, the sliding groove 7 is not formed over the entire length of both sides of the slit 6 but is formed only up to the middle portion.
  A leg portion 8 is formed in front of the rear shaft 3. The leg portion 8 is formed by forming the slit 6. Therefore, the number of legs 8 also changes depending on the number of cursive letters. Further, the lengths of the leg portions 8 are not the same but different. Specifically, the upper leg is formed shorter than the two lower legs 8 in FIG. As will be described later, this facilitates the assembly of the rear shaft 3 to the middle shaft 5.
  Reference numeral 9 is a clip portion formed on the side surface of the rear shaft 3.
[0009]
  In the slit 6 of the rear shaft 3, sliders (pressing members) 11 and 12 for protruding and retracting a ball pen, each having a concavo-convex portion 10 formed at a portion where the finger abuts, and a slider 13 for protruding and retracting a sharp pencil. Are slidably arranged. Sliding projections 14 are formed on both sides of the sliders 11 to 13 in the longitudinal direction, and are slidably engaged with the sliding grooves 7 formed in the slit 6. Two release protrusions 15 and 16 are formed on the back surfaces of the sliders 11 to 13 at intervals, and a ballpoint pen 17 that is a cursive body is formed on the front ends of the sliders 11 and 12. A spherical connecting portion 18 for connecting the two is formed. On the other hand, a press-fit portion 20 for connecting the sharp pencil 19 is formed at the front end portion of the other slider 13.
[0010]
  Here, a knock groove 21 is formed in the longitudinal center of the slider 13 for projecting and retracting the sharp pencil, and an L-shaped connecting rod 22 is slidably disposed in the knock groove 21. Has been. Further, a knock piece (knock member) 23 that gives a movement to the connecting rod 22 is fixed to one end of the connecting rod 22. Reference numeral 24 denotes a protrusion fixed to the intermediate portion of the connecting rod 22, and the protrusion 24 slides in a concave portion 25 formed in the intermediate portion of the slider 13, thereby connecting the connecting rod 22 and the knock. The rotation of the piece 23 and the protrusion from the shaft body 1 are prevented. Reference numeral 26 attached to the tip of the connecting rod 22 is a pressing member that presses the rear end of a core tank, which will be described later, and has a diameter slightly larger than the diameter of the connecting rod 22.
  Further, reference numeral 27 denotes an elastic member such as a coil spring that biases the two ball pens 17 and the sharp pencil 19 and the sliders 11 to 13 connected to the writing bodies backward.
[0011]
  A regulating portion 28 is formed at an intermediate portion of the middle shaft 5 that is one member of the front shaft 2, and three through holes 29 into which the writing body is loosely inserted are formed in the regulating portion 28. . The cursive body is urged backward by engaging one end of the elastic member 27 with the restricting portion 28.
  Also, three grooves 30 are formed in the longitudinal direction on the inner side of the middle shaft 5 and behind the restricting portion 28, and the leg portions 8 of the rear shaft 3 are slidably contacted with the grooves 30 so that the leg portions are assembled during assembly. 8 is guided.
[0012]
  A tip member 4, which is another member of the front shaft 2, is detachably fixed to the middle shaft 5 by screwing. The tip member 4 and the center shaft 5 may be integrally formed. However, in consideration of replacement of the writing body such as the ball pen 17 and the sharp pencil 19 and ease of molding, the tip member 4 and the center shaft 5 are fixed to be detachable. Better to do.
  Further, the inner side of the tip member 4 is curved, but the inclination angle of the tangent line is set smaller than the inclination angle of the line connecting the tip of the cursive body and the diameter portion of the cursive body. This is such that when the cursive body moves, the tip of the cursive body does not come into contact with the inner wall surface of the tip member 4, and recently, a transparent shaft has become popular, and contamination of the inner surface of the shaft has been prevented. . In the case of conventional writing instruments, particularly when the writing body is a ball pen, the ink adheres to the inner surface of the shaft, which deteriorates the appearance.
[0013]
  Next, the sharp pencil 19 will be described (see FIG. 6). A rear end of an outer shaft (outer member) 31 made of a resin or preferably a metal pipe is connected to a press-fitting portion (connecting portion) 20 of the slider 13. A tip member 33 is fixed to the tip of the outer shaft 31 by press-fitting or the like via a relay member 32. A lead core feeding mechanism 34 is slidably disposed inside the outer shaft 31, the intermediate member 32, and the tip member 33. The lead lead feeding mechanism 34 opens and closes a lead tank 35 made of a resin pipe such as polyethylene or polypropylene, a chuck body 37 fixed to the front of the lead tank 35 via a connecting member 36, and the chuck body 37. A chuck ring 38 and a chuck spring 39 that constantly biases the chuck body 37 backward are formed. Reference numeral 40 denotes a lead detent member that prevents the lead from retreating during feeding.
  In this example, the intermediate member 32 is press-fitted inside the front end of the outer shaft 31. However, considering the ease of replenishment of the core, as shown in FIG. The rear part of the member 32 may extend longer than the chuck spring 39 and may be press-fitted outside the front end of the outer shaft 31.
[0014]
  Next, the operation will be described. When the slider 13 connected to the sharp pencil 19 is pressed forward (downward in the figure), the slider 13 moves forward with the sharp pencil 19 while being guided by the slit 6 and the sliding groove 7. -The tip of the tip member 33 of the ppencil 19 protrudes from the tip of the shaft body 1. At the same time, the slider 13 is pushed into the shaft body 1, and then the rear end of the sliding projection 14 formed on the side surface of the slider 13 is brought into the step 7 a at the front end of the sliding groove 7. Engage and prevent the retracting action of the sharp pencil 19 (see FIGS. 1 and 4). That is, by forming the sliding groove 7 only up to the middle part of the slit 6, the slider 13 is also engaged.
[0015]
  Here, in order to pay out the lead, the knock piece 23 is pressed (advanced). As the knock piece 23 advances, the pressing portion 26 of the connecting rod 22 presses the rear end of the lead tank 35. By this pressing operation, the chuck body 37 moves forward against the elastic force of the chuck spring 39. The lead is advanced from the tip member 33 as the chuck body 37 advances.
[0016]
  Next, when it is desired to store the sharp pencil 19 in the shaft body 1, the other sliders 11 and 12 are pressed. When the other slider is pressed, the release protrusion 16 formed on the back surface of the other slider collides with the release protrusion 15. Due to this collision action, the slider 13 in the pressed state is pressed toward the outside of the shaft body 1. Then, by this pressing action, the engagement between the sliding projection 14 of the slider 13 and the step 7a of the sliding groove 7 is released, and the sharp pencil 19 which is projected by the releasing action is elastically repelled. The member 27 is retracted by the action of the member 27 and is immersed in the shaft body 1.
  In this example, the elastic force of the chuck spring 39 is set to be larger than that of the elastic member 27, but the reverse state may be set, that is, the elastic member 27 is more elastic than the chuck spring 39. Although the elastic force may be set larger, when the sharp pencil is protruded, the chuck spring is protruded in a pressed state, and the lead can be extended simultaneously. In such a case, the pressure input to the outer shaft 31 of the slider 13 is set large. Specifically, it is set to such an extent that it does not fall out due to the elastic force of the elastic member 27.
[0017]
  Next, modified examples of the sharp pencil will be described with reference to FIGS. This is a so-called side knock-type sharp pencil that feeds the lead by pressing the knock piece 41 against the shaft cylinder 1 in the radial direction. The description of the same configuration as the previous example is omitted.
  In this example, the slit 6 formed at the rear of the shaft cylinder 1 is formed to be slightly wider. The slit 6 has a knock piece 41 having a U-shaped cross section at the front end in the radial direction. Is arranged so that it can be pressed and rotated freely. As shown in FIG. 8, the knock piece 41 is formed with an engaging projection 42 for the shaft tube 1 at the front end portion, and from the shaft tube 1 on the rear side surface portion. An engaging claw 43 is formed to prevent the slipping out.
  On the other hand, a sliding recess 46 having an inclined surface 45 is formed in an intermediate portion of the slider 44 of this example corresponding to the slider 13 of the above example. Further, a taper member 48 having a chevron inclined surface is fixed to one end of the connecting rod 47 of this example corresponding to the connecting rod 22 of the above example.
  The taper member 48 is also moved forward by the advancement of the slider 44, and when the taper member 48 is pressed by the knock piece 41, the connecting rod 47 is moved forward, and the core is moved. It is paid out.
  A rotation preventing projection 49 is also formed at an intermediate portion of the connecting rod 47 of this example.
[0018]
  Next, an example in which the slider 50 of the sharp pencil 19 is embedded in the shaft body 1 will be described with reference to FIGS. In this example, the uneven portion 10 formed on the slider 13 of the previous example is not formed, and a portion corresponding to the uneven portion 10 is formed on the knock piece 51. Specifically, the knock piece 51 is formed longer than the previous knock piece 23 toward the rear, so that the slider 50 is hidden.
  Next, the operation will be described. In the state shown in FIG. 10, when the knock piece 51 interlocked with the sharp pencil 19 is pressed forward (downward in the figure), the pressing portion 26 of the connecting rod 22 contacts the rear end of the core tank 35 of the sharp pencil 19. Press. The outer shaft 31 is also moved forward by the pressing operation of the lead tank 35. This is because the elastic force of the chuck spring 39 is set larger than that of the elastic member 27. As the outer shaft 31 moves forward, the slider 50 connected to the outer shaft 31 also moves forward while being guided by the slit 6 and the sliding groove 7. The rear end of the sliding protrusion 14 that is pushed inward and formed on the side surface portion of the slider 50 engages with the step portion 7a at the front end of the sliding groove 7 to prevent the sharp pencil 19 from retracting. (See FIG. 12). At this time, the tip of the tip member 33 of the sharp pencil 19 protrudes from the tip of the shaft body 1.
  Further, in this example, the knock piece 23, the connecting rod 22, the protrusion 24, and the pressing portion 26 in the previous example are formed by integral molding.
  Thus, in this example, the appearance is improved by embedding the slider in the shaft body, and the peripheral parts of the knock piece are integrally formed, whereby the cost of the parts and the ease of assembly can be achieved.
  In the pressing operation, all the pressing force must be applied to the knock piece 51 as compared with the previous example. Therefore, as shown in FIG. 13, the uneven portion 10 of the knock piece 51 is formed larger in the lateral direction. Thus, the resistance force to the finger to be pressed may be diffused and softened.
[0019]
  Next, a modification of the sharp pencil will be described with reference to FIGS. This is a so-called side knock-type sharp pencil that extends the core by pressing the knock piece 52 against the shaft body 1 in the radial direction.
  The slit 6 formed on the rear side of the shaft body 1 is slightly wider than the previous example. However, the slit 6 may have the same width, and the slit 6 has a cross section. A U-shaped knock piece 52 is arranged in the radial direction so as to be able to be pressed and rotated around the rear end. The knock piece 52 has a fixed shaft 53 formed at the rear end portion, and a pressing protrusion 55 that presses a slider 54 described later is formed on the front inner surface. An engagement claw 55 a that prevents the knock piece 52 from coming off from the shaft body 1 is formed on the pressing protrusion 55.
  On the other hand, a support hole 56 in which the fixed shaft 53 of the knock piece 52 is rotatably fixed is formed at the rear end portion of the slider 54 of the present example corresponding to the slider 50 of the example. As shown in FIG. 16, the rear end (convex portion 52a) of the knock piece 52 and the rear portion (concave portion 54a) of the slider 54 may be engaged with each other. Also in this example, a notch 25 is formed in the middle of the slider 54. In addition, a taper member 58 having a mountain-shaped inclined surface is formed at one end portion of the connecting rod 57 of this example corresponding to the connecting rod 22 of the above example. It may be fixed.
  As the knock piece 52 advances, the connecting rod 57 and the sharp pencil 19 advance. As the sharp pencil 19 advances, the slider 54 also advances. Then, the taper member 58 and the connecting rod 57 are pushed forward by the pressing operation of the knock piece 52 in the radial direction, and the lead is drawn out.
[0020]
  Next, a modified example of the outer shaft 31 will be described. By making the outer shaft 31 bend easily, the outer shaft 31 is made to protrude smoothly from the shaft body 1. Hereinafter, various modifications will be described. The outer shaft 31 may be made of a resin-made flexible member such as polypropylene, polystyrene, or polybutylene terephthalate. However, if the outer shaft is bent or contracted by writing, it is made of metal. Is preferred.
  FIG. 17 is a view showing the first modification, in which a notch 60 is formed behind the metal outer shaft 59, but the outer shaft 31 is divided into two parts from the intermediate portion as shown in FIG. However, they may be connected by a pipe 61 in which a cut 60 is formed. The notches 60 are formed vertically at opposite positions in a range of about 150 degrees and with a phase shift of 90 degrees. In consideration of the case where the sharp pencil 19 has been rotated, it is possible to bend even if a force is applied from any direction. The notch 60 is formed at the rear of the length of the core to be used, starting from the front end of the tip member 33. This is to prevent breakage of the lead in the lead tank 35 due to the bending action at the notch 60 portion of the outer shaft 59 (31).
[0021]
  FIGS. 19 and 20 are views showing a second modification, in which a spiral cut 63 is formed in the outer shaft 62. FIG. 19 shows an example in which the outer shaft 62 is formed in one part of the intermediate portion, and FIG. 20 shows an example in which the outer shaft 62 is formed in the entire longitudinal direction. By forming the notch 63 in a spiral shape, an elastic action is generated in the outer shaft 62, and it is curved when the sharp pencil advances.
  FIG. 21 is a view showing a third modification, in which an outer member (an outer shaft corresponding to the previous example) is a coil spring 64. Compared to the second modified example, the entire longitudinal direction is easily curved, and by using a commercially available coil spring, the labor of processing can be saved and the manufacturing can be made at low cost.
[0022]
  FIG. 22 is a view showing a fourth modified example, in which a longitudinal notch 66 is formed on the side wall of the outer shaft 65. The lead tank 35 is formed of a transparent material such as polyethylene or polypropylene so that the remaining amount of the lead can be confirmed. The notch 66 is formed in the cylindrical outer shaft 65. However, a notch is formed in advance in a flat plate member serving as the outer shaft, and then the plate member is rounded into a cylindrical shape. None may be used as the outer shaft. FIG. 23 is a diagram in which the sharp pencil 19 according to the fourth modification is mounted on the shaft body 1, and is attached so that the notch 66 is positioned in a direction in which the sharp pencil 19 is curved. Although considering the ease of bending, the notch 66 may be attached so as to be opposite to the position. The core in the core tank can be confirmed more easily. The orientation of the sharp pencil 19 (outer shaft 65) may be determined by the fitting position relationship between the slider 50 and the outer shaft 31.
[0023]
  FIG. 24 is a view showing a fifth modification example, in which the outer shaft 67 is divided into two and the outer shaft 67 divided into two is connected by caulking. The caulking portion 68 is caulked with a slight clearance (backlash), and is bent at the caulking portion 68.
  FIG. 25 is similar to the fifth modification, but is an example in which the outer shaft 67 is divided into two and the outer shaft 67 divided into two is connected by a heat-shrinkable resin tube 69. An adhesive is applied to the inner surface of the heat-shrinkable resin tube 69, and at the same time as the heat shrinkage, the adhesive melts and adheres to the outer shaft 67.
[0024]
  Next, a rotation prevention mechanism for the outer shaft slider will be described. In particular, this mechanism is effective when an outer shaft that has directionality with respect to the bending action of the outer shaft is used as in the fourth modification. The outer shaft does not rotate with respect to the slider, and can always be fixed in a direction that tends to bend.
  A first example will be described with reference to FIGS. On the rear side of the outer shaft 65, an engaging protrusion 72 is formed which engages with the concave portion 71 of the fitting portion 70 of the slider 50 and prevents mutual rotation.
In this example, the engaging protrusion 72 is formed by cutting the side surface of the outer shaft 65 into a U-shape and bending it inward, but as shown in FIGS. May be folded inward in a rectangular shape. Further, although the engaging protrusions 72 are provided at two opposing positions, this is to ensure the engagement (connection) between the outer shaft 65 and the slider 50, and there may be one. The engagement between the recess and the engagement protrusion is in an engagement state in which the outer shaft and the slider can be bent with the engagement portion as a fulcrum. In addition, in order to increase the ease of protruding and retracting the sharp pencil 19 from the shaft main body 1, a window portion 66 is formed at an intermediate portion of the outer shaft 65 so that the outer shaft 65 is easily bent. The notch 66 is formed on a surface that is 90 degrees different from the engagement protrusion 72 in consideration of bending at the engagement portion (engagement between the recess 71 and the engagement protrusion 72). . That is, as described above, the curvature of the notch 66 and the bending at the engaging portion improve the appearance of the sharp pencil from the shaft tube. In addition, by bending at the engaging portion, there is an effect that the bending of the outer shaft is reduced and the core can be fed out satisfactorily.
  The outer shaft 65 in this example is formed in a cylindrical shape by rounding a plate-shaped metal plate on which engagement protrusions and window portions are formed in advance. The mating protrusion and the window portion may be formed by cutting or the like.
[0025]
  FIG. 32 is a diagram showing a second example, in which a concave portion (square hole) 73 is surrounded by a concave portion serving as an engagement receiving portion. Then, by making the width of the recess 73 the same as the width of the engaging projection 72 of the outer shaft 65, the outer shaft 65 and the slider 50 are less likely to be bent, but the outer shaft 65 and the slider can be more reliably secured. 50 can be fixed, and accidental rotation of the outer shaft 65 and the slider 50 by operation is further prevented.
  FIG. 33 is a diagram showing a third example, in which one side of the recess 73 of the second example is opened. Specifically, the side in the direction of the groove 21 is open. Compared to the second example, the flexibility of the outer shaft 65 and the slider 50 is improved, and the mold for molding the slider 50 is simplified.
[0026]
  FIG. 34 is a view showing a fourth example, in which the engaging protrusion 72 formed on the outer shaft 65 is formed to be parallel to the surface of the outer shaft 65, and the parallel engaging protrusion 74 is formed. This is an example in which the concave portion 73 is brought into surface contact. The outer shaft 65 and the slider 50 are securely fixed. Even in the case of a taper-like engagement protrusion 72 as shown in FIG. 27, the concave portion 73 is formed in a taper shape so that it can be brought into surface contact and the fixing reliability can be improved. .
  FIG. 35 and FIG. 36 are views showing a fifth example, in which the arrow-shaped protrusion 75 is formed on the slider 50 instead of the recess, and the outer shaft 65 is engaged with the protrusion 75. This is an example in which an engagement hole 76 is formed. This facilitates the processing of the engagement receiving portion (engagement hole 76).
[0027]
【The invention's effect】
  The present invention has a plurality of writing bodies including at least one sharp pencil in the shaft body, and the writing bodies are urged rearward by an elastic member, but are attached to the rear end of the writing body. In the multi-core writing instrument which makes the writing body protrude from the shaft body by advancing the pressing member beingA slit is formed in the shaft body, and the pressing member is slidably disposed in the slit.The sharp pencil has an outer member connected to the pressing member, a tip member fixed to the tip of the outer member, and a lead core feeding mechanism slidably arranged inside the outer member and the tip member. In addition, since the knock member for operating the lead lead feeding mechanism is arranged on the pressing member, the lead does not immerse during writing, and the spring resilience of the spring of the lead feeding mechanism is not increased. And the core is not broken by the holding force of the core.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line AA of FIG. 1 when the slider 13 is retracted.
3 is a cross-sectional view taken along the line BB of FIG. 1 when the slider 13 is retracted.
4 is an enlarged view of a portion C in FIG.
FIG. 5 is a perspective view showing parts of the slider-peripheral portion of the present invention.
FIG. 6 is a longitudinal sectional view of a main part showing a sharp pencil.
FIG. 7 is a longitudinal sectional view of an essential part showing a modified example of a sharp pencil.
FIG. 8 is a longitudinal sectional view showing a modification of the present invention.
FIG. 9 is a perspective view showing a peripheral part of a slider according to a modification.
FIG. 10 is a longitudinal sectional view showing a modification of the present invention.
11 is a perspective view showing parts in the periphery of the slider in FIG. 10;
12 is an enlarged vertical sectional view of the main part of FIG.
FIG. 13 is a perspective view showing a modified example of the slider.
FIG. 14 is an enlarged vertical sectional view showing a main part of a modification of the present invention.
15 is a perspective view showing parts in the periphery of the slider in FIG. 14;
FIG. 16 is a perspective view showing a modification of FIG.
FIG. 17 is an external view showing a first modification of the outer shaft.
18 is an external view showing a modification of FIG.
FIG. 19 is an external view showing a second modification of the outer shaft.
20 is an external view showing a modification of FIG.
FIG. 21 is an external view showing a third modification of the outer shaft.
FIG. 22 is an external view showing a fourth modification of the outer shaft.
FIG. 23 is an essential part longitudinal cross-sectional view showing a state in which a fourth modification of the outer shaft is incorporated in the shaft main body.
FIG. 24 is an external view showing a fifth modification of the outer shaft.
FIG. 25 is an external view showing a sixth modification of the outer shaft.
FIG. 26 is a longitudinal sectional view of the main part of the front surface of the outer shaft showing a first example of the rotation preventing mechanism.
27 is a side view of FIG. 26. FIG.
FIG. 28 is a perspective view showing a slider of the first example.
FIG. 29 is a longitudinal sectional view of an essential part showing a state where the shaft body and the slider of the first example are assembled.
30 is a main part front view showing a modification of FIG. 26. FIG.
31 is a sectional view taken along line DD in FIG. 30. FIG.
FIG. 32 is a perspective view of a slider showing a second example of the rotation preventing mechanism.
FIG. 33 is a perspective view of a slider showing a third example of the rotation preventing mechanism.
FIG. 34 is a longitudinal sectional view of a main part in which an outer shaft and a slider are assembled, showing a fourth example of a rotation prevention mechanism.
FIG. 35 is a perspective view of a slider showing a fifth example of the rotation preventing mechanism.
FIG. 36 is a longitudinal sectional view of an essential part showing a state in which the outer shaft and the slider of the fifth example are assembled.
[Explanation of symbols]
  1 axis body
  2 Front shaft
  3 Rear axle
  4 Tip member
  5 Center shaft
  6 Slit
  7 Sliding groove
  7a Front end step
  8 legs
  9 Clip part
  10 Concavity and convexity
  11 Slider (Pressing member)
  12 Slider (Pressing member)
  13 Slider (Pressing member)
  14 Sliding projection
  15 Release protrusion
  16 Release protrusion
  17 Ball pen (cursive)
  18 connections
  19 Sharp pencil (cursive)
  20 Press-in part
  21 Knock groove
  22 Connecting rod
  23 knock piece
  24 protrusions
  25 recess
  26 Pressing part
  27 Elastic member
  28 Regulatory Department
  29 Through hole
  30 Groove
  31 Outer shaft (outer member)
  32 Joint members
  33 Tip member
  34 Centering mechanism
  35 core tank
  36 Connecting members
  37 Chuck body
  38 Chuck ring
  39 Chuck spring
  40 Detent member
  41 knock piece
  42 Engaging projection
  43 engaging claw
  44 Slider
  45 Inclined surface
  46 recess
  47 Connecting rod
  48 taper member
  49 Protrusion
  50 slider
  51 knock piece
  52 knock piece
  53 Fixed shaft
  54 Slider
  55 Pressing protrusion
  56 Support hole
  57 Connecting rod
  58 taper member
  59 Outer shaft
  60 notches
  61 pipe
  62 Outer shaft
  63 notches
  64 Coil spring
  65 outer shaft
  66 Notch
  67 Outer shaft
  68 Caulking part
  69 Resin Tube
  70 Insertion
  71 recess
  72 Engagement protrusion
  73 recess
  74 Engagement protrusion
  75 protrusions
  76 engagement hole

Claims (4)

The shaft body has a plurality of writing bodies including at least one sharp pencil, and the writing bodies are urged rearward by an elastic member, but the pressing member attached to the rear end of the writing body In the multi-core writing instrument in which the writing body is projected from the shaft main body by moving forward, the slit is formed in the shaft main body, and the pressing member is slidably disposed in the slit, The sharp pencil has an outer member connected to the pressing member, a tip member fixed to the tip of the outer member, and a lead core feeding mechanism slidably disposed inside the outer member and the tip member, A multi-core writing instrument, wherein a knock member for operating the lead core feeding mechanism is disposed on the pressing member. 2. The multi-core writing instrument according to claim 1, wherein the mechanical pencil pressing member is embedded in the shaft body.   The multi-core writing instrument according to claim 1, wherein the outer member is a flexible member.   The shaft body has a plurality of writing bodies including at least one sharp pencil, and the writing bodies are urged rearward by an elastic member, but the pressing member attached to the rear end of the writing body In the multi-core writing instrument in which the writing body is projected from the shaft body by being advanced, the sharp pencil is fixed to the tip of the outer member and the outer member that are non-rotatably connected to the pressing member. A lead core feeding mechanism that is slidably disposed inside the member, the outer member, and the tip member, and a knock member that operates the lead core feeding mechanism is disposed on the pressing member, and the outer member A multi-core writing instrument characterized by comprising a flexible member.

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