JP2007044816A - Inclined cutter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inclined cutter which simplifies the cutting operation without requiring so much skill and achieves almost uniform finishing surface of cutting surface without depending on a worker. <P>SOLUTION: A slide operation part 170 for holding a blade 300 is mounted in a slot 130 having an inclined slide base. The blade 300 is relatively slidably connected to a slide operation part 170 in an extending direction of a slot 130 through a spring 160, and energized in the direction projected to the outside of the slot relative to the slide operation part 170. When the slide operation part 170 is in a storage position, a blade tip end 301 is stored in the slot even when the blade 300 is energized to the most projecting side by the spring. On the other hand, when the slide operation part 170 is at the projected position, the blade tip end is projected from the slot by a certain distance, when the blade is energized to the most projecting side by the spring. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an inclined cutter for cutting a cutting target such as a sheet or cardboard having a certain thickness obliquely with respect to the thickness direction.

As such an inclined cutter, for example, those disclosed in Patent Document 1 and Patent Document 2 are known.
However, none of the cutters of Patent Document 1 and Patent Document 2 includes a feed mechanism that finely adjusts the protruding amount of the blade edge during the cutting operation. Therefore, the user needs to adjust the feed amount of the blade edge with the sense of the hand while sliding the cutter left and right, and requires considerable skill in the cutting operation.

Japanese Utility Model Publication No. 57-136694 Japanese Patent No. 3484605

  In view of the above circumstances, an object of the present invention is to provide an inclined cutter that can be easily cut without much skill, and that the finish of the cut surface is almost uniform regardless of the operator. .

The present invention provides an inclined cutter having the following features.
The inclined cutter of the present invention includes a “slide table for holding the blade so that it can be taken in and out” and a “guide member that engages with the slide table and guides the slide so as to be able to reciprocate”. Alternatively, the inclined cutter may be constituted by a single “sliding base that holds the blade so that it can be taken in and out and slides back and forth while being guided by the guide member”.
The slide table includes a “slot that extends at an angle with respect to the slide surface” and a “slide operation unit that holds the blade and is slidably mounted in the slot”.
The blade is connected to the slide operation unit through the biasing member so as to be relatively slidable in the extending direction of the slot, and is moved to the outside of the slot with respect to the slide operation unit by the biasing member. It is biased in the protruding direction.
The slide operation part is “the storage position where the blade tip is stored in the slot even when the blade is urged to the most protruding side by the urging member” and “the blade is urged to the most protruding side by the urging member” The blade tip can be selectively fixed in the slot at the “projection position where the blade tip projects from the slot by a certain distance”.

In the inclined cutter of the present invention having the above-described configuration, the blade is positioned so that the tip of the blade protrudes to the outside by a predetermined amount only by fixing the slide operation portion at the protruding position. When the blade tip is pressed against the object to be cut, the blade tip is retracted into the slot by the pressing force, but is biased by the biasing means to a position where the tip protrudes by the predetermined amount.
Therefore, when the slide table is reciprocated on the object to be cut, the blade tip gradually protrudes into the object to be cut by the biasing force of the biasing means, and finally the position where the tip protrudes by the predetermined amount. Return. The blade tip does not protrude any further. In addition, the protruding amount at this time (the amount of biting into the object to be cut) is fixed in advance.
In other words, the amount of biting on the object to be cut is the same regardless of who operates it, and the blade tip gradually increases its protruding amount as the slide base is reciprocated several times during the cutting operation. Is finished beautifully.
In this way, the depth of the cutting part is constant regardless of the operator, and the protruding amount of the blade tip is gradually increased by using the biasing means, so that the variation by the operator with respect to the finish of the cut surface is Almost disappear.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. FIG. 1 is a perspective view showing an inclined cutter according to an embodiment of the present invention.
The inclined cutter includes a slide base 100 and a guide member 200. As will be described later, the slide base 100 holds the blade 300 so that it can be taken in and out, and slides back and forth while being guided by the guide member 200.

The guide member 200 is an elongated plate-like member, and has a linear guide groove 201 extending along one side thereof. The slide table 100 has an engaging portion 101 on the bottom surface side along the front end.
The slide base 100 slides back and forth along the guide member 200 in a state where the engaging portion 101 is engaged in the guide groove 201 of the guide member 200 (see FIG. 2).

  This inclined cutter is used, for example, to create a decorative frame for a frame by cutting out a piece of cardboard. FIGS. 3A and 3B show a decorative frame 1 created by this inclined cutter. The decorative frame 1 is a frame-shaped body obtained by cutting out the central portion 1a of a piece of cardboard. As can be seen from the partially broken view of FIG. 3B, the cut surface is inclined with respect to the surface of the frame.

≪Configuration of slide table 100≫
FIG. 4 is an exploded view showing the structure of the slide base 100 and the slide operation unit 170. The slide table 100 includes a pedestal portion 110 that slides on the surface of a cutting target (for example, the above-described cardboard), and an inclined portion 120 provided on the pedestal portion.
The pedestal part 110 slides on the surface in a state where the back surface (slide surface) is in contact with the surface to be cut.
In the center of the inclined portion 120, a straight slot 130 extending along the inclination is formed. In this slot 130, the slide operation part 170 holding the blade 300 is slidably mounted.

<< Configuration of Slide Operation Unit 170 >>
The slide operation unit 170 includes a main body 171 and an operation plate 176. An engagement protrusion 180 is incorporated in the main body 171 so as to be slidable in the lateral direction (arrow B direction). The engaging protrusion 180 is urged outward by a spring 188 and normally protrudes to the side of the slide operation unit 170.
The operation plate 176 is fitted to the main body 171 so as to be relatively slidable. An engagement hook 177 is erected on the back surface of the operation plate 176 (see FIG. 5A). The engagement hook 177 is slidably engaged in an engagement hole 173 formed on the upper surface of the main body 171. Match. As a result, the operation plate 176 can be slid relative to the main body 171.
Further, an inclined surface 178 is formed on the back surface of the operation plate 176 (see FIG. 6), and this abuts on an inclined surface 181 formed integrally with the engaging protrusion 180. Since the engagement protrusion 180 is urged in the protruding direction by the spring 188, the operation plate 176 is normally positioned on the most front side (arrow A direction) with respect to the main body 171 by this urging force. Become.

  As will be described later, when the operation plate 176 is pulled rearward, the operation plate 176 slides rearward relative to the main body 171, and the inclined surface 178 on the back surface of the operation plate 176 presses the inclined surface 181. As a result, the engagement protrusion 180 is retracted (retracted) into the slide operation unit 170 against the urging force of the spring 188.

<< Connection between the slide operation unit 170 and the blade 300 by the spring 160 >>
The blade 300 is connected to the slide operation unit 170 via the spring 160. By this spring 160, the blade 300 is urged with respect to the slide operation portion 170 in a direction protruding from the slot (arrow A direction).
In the illustrated example, the blade 300 is fixedly fixed to the blade holder 150, and the blade 300 is connected to the spring 160 via the blade holder 150. However, in the present invention, it is only necessary that the blade 300 itself is urged in the protruding direction with respect to the slide operation unit 170, and therefore other configurations can be adopted.

  The blade holder 150 has two protrusions 156 formed on the back surface, and these protrusions 156 engage with the locking holes 302 formed in the blade 300 (see FIG. 5B). That is, the blade 300 is fixed to the blade holder 150 in a stationary manner and behaves integrally therewith.

An engagement hook 175 that protrudes downward is formed in the main body 171 of the slide operation unit 170, and the engagement hook 175 is slidably engaged in an engagement hole 155 formed in the blade holder 150. . As a result, the slide operation unit 170 and the blade holder 155 (that is, the slide operation unit 170 and the blade 300) are coupled so as to be slidable relative to each other.
One end of the spring 160 is fixed to the locking part 152 on the blade holder side, and the other end is fixed to the locking part 172 on the slide operation part side. By this spring 160, the blade holder 150 is biased relative to the slide operation unit 170 in the direction of arrow A (that is, in the direction in which the blade 300 protrudes forward from the slot 130).

≪Three engagement positions≫
As already described, the slide operation unit 170 includes the engagement protrusion 180 protruding from the side surface. The engagement protrusion 180 is urged in a protruding direction by a spring 188 so as to be retractable (can be retracted).
On the other hand, in the illustrated example, three engaging recesses 131, 132, and 133 are formed on the side surface of the slot 130 along the longitudinal direction. The slide operation portion 170 can be fixed at three different positions in the slot 130 by engaging any one of the three engagement recesses 131, 132, and 133 with the engagement protrusion 180.

(1) When the engagement protrusion 180 is engaged with the engagement recess 131 (storage position)
In this case, the slide operation unit 170 is in the “storage position”. That is, in this state, even when the blade 300 is urged to the most projecting side by the spring 160, the blade tip 301 does not project outside from the slot 130 and is housed in the slot 130. Yes.

(2) When the engagement protrusion 180 is engaged with the engagement recess 132 (first protruding position)
In this case, the slide operation unit 170 is in the “first protruding position”. That is, in this state, when the blade 300 is urged to the most projecting side by the spring 160, the blade tip 301 projects from the slot 130 by a “certain distance”.
By placing the guide member 200 along a desired cutting line on a cutting target (such as cardboard) and sliding the slide table 100 in this state, the cutting operation can be performed. The amount of biting of the blade tip 301 with respect to the object to be cut (that is, the cutting depth) is equal to the above “fixed distance”.

(3) When the engagement protrusion 180 is engaged with the engagement recess 133 (second protruding position)
In this case, the slide operation unit 170 is in the “second protruding position”. That is, even in this state, the blade tip 301 protrudes from the slot 130 as in the case where the engagement recess 132 is engaged. However, the protruding amount (biting amount) of the blade tip 301 is larger than that in the “first protruding position”.

  Although not shown in the figure, a larger number of engaging recesses are formed on the side surface of the slot, and a “third protruding position”, a “fourth protruding position”,. Also good.

«Pressure contact mechanism to prevent rattling of blade 300»
In the present invention, the slide operation unit 170 holding the blade 300 slides in the slot 130. A mechanism for preventing the backlash of the blade 300 during the sliding and making the finish of the cut surface clean will be described with reference to FIG.
FIG. 5B shows the blade holder 150 and the slide operation unit 170 in a combined state from the side. Fig.5 (a) is the sectional view on the aa line in FIG.5 (b).

  Inclined cam surfaces 170 a and 170 b are formed on the lower surface side of the main body 171 of the slide operation unit 170, while inclined cam surfaces 150 a and 150 b are formed on the upper surface side of the blade holder 150. As described above, the slide operation unit main body 171 and the blade holder 150 are connected by the spring 160 and are urged in a direction to attract each other. As a result, the inclined cam surfaces 150a and 170a are in pressure contact, and the inclined cam surfaces 150b and 170b are in pressure contact.

  As described above, due to the cooperation between the inclined cam surfaces 150a and 170a and the cooperation between the inclined cam surfaces 150b and 170b, a force in the upward direction (arrow U) in the drawing acts on the slide operation unit main body 171 and the blade A downward force (arrow D) in the figure acts on the holding body 150. That is, when mounted in the slot 130 in this state, the slide operation unit 170 and the blade holder 150 are pressed against the opposing wall surfaces in the slot 130, respectively. As a result, rattling of the blade 300 in the slot 130 can be prevented.

  In this way, by preventing rattling of the blade 300 in the slot 130, for example, even when the object to be cut is a sheet having a large resistance, such as thick mat paper, it can be cut cleanly.

  In addition to the configuration shown in the figure, if a compression coil spring (not shown), which is a separate member, is sandwiched between the blade holder 150 and the slide operation section main body 171, etc. The backlash of the blade 300 can be prevented. However, if an inclined cam surface is used as in the illustrated example, the urging force of the spring 160 can be used in combination to prevent rattling, and there is an advantage that the number of parts can be saved.

≪Auto-lock mechanism≫
As described above, in the illustrated inclined cutter, the position of the slide operation unit 170 is fixed by engaging the engagement protrusion 180 with any of the engagement recesses 131, 132, 133 provided along the slot. The Then, the position of the slide operation unit 170 (and the blade 300) can be slid by operating the operation plate 176 of the slide operation unit 170 with a finger. On the other hand, when an external force is directly applied to the blade 300, the position of the slide operation unit 170 is fixedly fixed against the external force (auto-lock mechanism).
That is, the operation of the auto-lock mechanism is as follows.
(I) By operating the operation plate 176 of the slide operation unit 170, it is possible to push the slide operation unit 170 forward or store it on the front side (rear side).
(Ii) When an external force in the storage direction directly acts on the blade 300, the slide operation unit 170 is locked against the external force.

  The operation of each component for realizing the above functions will be described below with reference to FIG. FIG. 6 schematically shows the slide operation unit 170 in the slot 130.

(1) When the slide operation unit 170 is operated forward, it is assumed that the engagement protrusion 180 is engaged in the engagement recess 131 and the slide operation unit 170 is in the “storage position” (in FIG. 6). Dashed line). From this state, when the slide operation unit 170 is slid forward (in the direction of arrow A) (in this case, the operation plate 176 of the slide operation unit 170 is actually pressed forward with a finger), the engagement protrusion 180 The inclined surface 180a on the front side is in pressure contact with the inclined surface 131a on the front side of the engaging recess 131. In that case, the engagement protrusion 180 retracts against the urging force of the spring 188 (retracts) by cooperation of the inclined surfaces. As a result, the slide operation unit 170 slides forward, and the engagement protrusion 180 engages with the next engagement recess 132.
Further, when the slide operation unit 170 is further slid forward by the same principle, the engagement protrusion 180 is detached from the engagement recess 132 and engaged with the next engagement recess 133.
As described above, the slide operation unit 170 can be slid forward by pushing the operation plate 176 of the slide operation unit 170 forward.

(2) When the slide operation unit 170 is operated backward It is assumed that the engagement protrusion 180 is engaged in the engagement recess 133 and the slide operation unit 170 is in the “second protruding position”. When the operation plate 176 is slid backward from this state, the operation plate 176 slides backward relative to the main body 171 of the slide operation unit. An inclined surface 178 is formed on the back surface of the operation plate 176, and the inclined surface 178 presses against an inclined surface 181 formed integrally with the engaging protrusion 180. Due to the cooperation between the inclined surfaces, the engaging protrusion 180 is retracted (retracted) against the urging force of the spring 188. As a result, the entire slide operation unit 170 slides rearward, and the engagement protrusion 180 engages with the next engagement recess 132.
Further, when the operation plate 176 of the slide operation unit 170 is further slid rearward on the same principle, the engagement protrusion 180 is detached from the engagement recess 132 and engaged with the next engagement recess 131.
As described above, the slide operation unit 170 can be slid backward by pulling back the operation plate 176 of the slide operation unit 170.

(3) When external force in the storage direction directly acts on the blade 300 Now, the engagement protrusion 180 is engaged in the engagement recess 133, and the slide operation part 170 is in the “second protruding position”, so that the cutting operation is performed. Is done.
During the cutting operation, external force in the storage direction directly acts on the blade 300 directly from the cutting object (unless the user operates the operation plate 176, no external force acts on the operation plate 176).
In this case, since the operation plate 176 does not move relative to the main body 171, the engagement protrusion 180 does not retract due to the cooperation of the inclined surfaces. That is, the engagement protrusion 180 protrudes to the outside and remains engaged with the engagement recess 133.
Here, the rear side surface 180b of the engagement protrusion 180 and the rear side surface 133b of the engagement recess 133 are not inclined surfaces but are upright surfaces extending substantially orthogonal to the extending direction of the slot 130. ing. Therefore, the rear side surface (upright surface) 180b of the engagement protrusion 180 is pressed against the rear side surface (upright surface) 133b of the engagement recess 133, thereby preventing the entire slide operation unit 170 from sliding backward (auto-locking). Act).
As described above, when an external force in the storage direction is directly applied to the blade 300, the slide of the slide operation unit 170 is locked.

  In addition, since all the engagement recessed parts 131, 132, and 133 are similarly formed in the shape which has an inclined surface and an upright surface, the same function is achieved with respect to any engagement recessed part. The same applies when four or more engaging recesses are provided.

  With such an auto-lock mechanism, it is possible to reliably prevent the slide operation unit 170 (and the blade 300) from retreating carelessly during the cutting operation without performing a special operation. On the other hand, when the user wants to store the blade 300, the blade 300 can be easily stored by simply pulling the operation plate 176 of the slide operation unit 170 backward with a finger.

In addition, as an auto-locking mechanism different from that shown in FIG. 6, an auto-locking mechanism that functions as an auto-locking mechanism may be employed regardless of whether the force acting directly on the blade acts in either the pull-out direction or the storage direction. That is,
(I) When an external force directly acts on the blade 300 in both the storage direction and the pull-out direction, the slide operation unit 170 is locked against the external force.
(Ii) By operating the operation plate 176 of the slide operation unit 170, it is possible to push the slide operation unit 170 forward or store it on the front side (rear side) (this point is This is the same as the auto-lock mechanism of FIG.

A specific configuration for achieving such automatic locking is, for example, as follows.
First,
(I) The front side (the lower side in FIG. 6) of each engagement recess 131, 132, 133 is changed to an upright surface. That is, both the front side (the lower side in FIG. 6) and the rear side (the upper side in FIG. 6) of each engagement recess are made upright. In addition, both side surfaces 180a and 180b of the engaging projection 180 are set to be upright surfaces so as to conform to this.
As a result, when an external force in the pull-out direction acts directly on the blade 300, the “upright front surface of each engagement recess 131, 132, 133” and the “upper front surface of the engagement protrusion 180” In pressure contact, the blade 300 is prohibited from sliding in the pull-out direction (auto-lock is activated). Similarly, when an external force in the storage direction directly acts on the blade 300, “an upright surface on the rear side of each engagement recess 131, 132, 133” and “an upright surface on the rear side of the engagement protrusion 180” In pressure contact, the blade 300 is prohibited from sliding in the storage direction (auto-lock is activated).
That is, in both the storage direction and the pull-out direction, when an external force directly acts on the blade 300 in the direction, the slide operation unit 170 is locked against the external force.
And
(Ii) Either one of “the inclined surface 181 integrally formed with the engaging protrusion 180” and “the inclined surface 178 formed on the back surface of the operation plate 176” is formed into a V-shaped inclined surface having two inclined surfaces. The other is an inverted V-shaped slope with two slopes that fit it. The operation plate 176 is configured to be slidable relative to the slide operation unit main body 171 in both the front and rear directions.
With such a configuration, even when the operation plate 176 is slid forward or backward with a finger, the engagement protrusion 180 is retracted by cooperation of the inclined surfaces, and the slide operation unit 170 is It is possible to slide forward or backward.

  In the above auto-lock mechanism, when the blade is inserted and removed, the operation plate 176 is always slid manually to release the auto-lock.

≪Example of actual cutting process≫
An example of a cutting process for cutting cardboard using the inclined cutter configured as shown in FIGS. 1 to 6 will be described with reference to FIGS. Each of FIGS. 7 to 12 schematically shows the engagement state of the slide operation unit 170 and the engagement recesses 131, 132, and 133 together with the sectional view of the inclined cutter during the cutting operation.

≪Figure 7≫
First, a guide member (ruler) 200 is set along a desired cutting line on the cardboard 400, and the slide table 100 is engaged with this. At this time, the slide operation unit 170 is engaged with the engagement recess 131 and is in the “storage position”. That is, the blade tip 301 is still accommodated in the slot 130 of the slide base 100 and does not protrude to the outside.

≪Figure 8≫
Next, the slide operation unit 170 is operated with a finger to be engaged with the engagement recess 132. At this time, the slide operation unit 170 is in the “first projecting position” and attempts to project the blade tip 301 to the outside by the urging force of the spring 160, but in reality, the blade is pushed back into the slot 130 by the cardboard 400. It is the result.
That is, the blade tip 301 is stabbed into the cardboard surface and is urged by the spring 160 to further penetrate into the cardboard.

≪Figure 9≫
In this state, the slide table 100 is reciprocated along the ruler 200. As this reciprocation is repeated, the blade tip 301 gradually enters the thick paper by the urging force of the spring 160.
When the slide operation unit 170 is in the “first protruding position”, the maximum protruding amount of the blade tip 301 is determined in advance. Therefore, if a thick paper having a thickness corresponding to the thickness is selected in advance, the blade tip 301 penetrates the thick paper, and the cutting is completed.

≪FIG. 10, FIG. 11≫
When the cutting is completed, the slide operation unit 170 is operated to be pulled back. In this case, since the engaging protrusion 180 is retracted into the slide operation unit 170, the slide operation unit 170 can be pulled back.
When the slide operation unit 170 reaches the “storage position”, the engagement protrusion 180 protrudes again and engages with the engagement recess 131.

≪Figure 12≫
In FIG. 12, the thick paper 401 has cut | disconnected the thicker thing than the case of FIGS. In that case, first, the slide operation unit 170 is set to the “first protruding position”, and is first cut to the middle position of the thick paper 401. Next, the slide operation unit 170 is set to the “second protruding position”. Thus, it is preferable to cut until the cardboard 401 is finally penetrated. This has the following advantages.

(I) The spring biasing force at the start of cutting can be prevented from becoming excessive. If the blade tip 301 bites deeply from the beginning, the cut surface will not be finished cleanly, but this can be prevented by going through a multi-step cutting process.
(Ii) It is possible to prevent a decrease in spring urging force when cutting is completed. If the urging force at the time of completion of cutting is insufficient, it takes time to penetrate, but by adopting a multi-stage cutting process, a sufficient urging force can be secured even at the time of completion of cutting.
In addition, you may further provide "3rd protrusion position", "4th protrusion position" ....

The perspective view which shows the inclination cutter which concerns on one Embodiment of this invention. The perspective view explaining the usage method of the inclination cutter of FIG. The perspective view explaining the decorative frame produced with the inclined cutter of FIG. The exploded view explaining the slide stand which comprises the inclination cutter of FIG. The figure explaining the structure of the slide operation part which comprises the inclination cutter of FIG. The schematic diagram explaining the principle of the auto-lock mechanism in the inclination cutter of FIG. The figure explaining an example of the concrete cutting process using the inclination cutter of FIG. The figure explaining an example of the concrete cutting process using the inclination cutter of FIG. The figure explaining an example of the concrete cutting process using the inclination cutter of FIG. The figure explaining an example of the concrete cutting process using the inclination cutter of FIG. The figure explaining an example of the concrete cutting process using the inclination cutter of FIG. The figure explaining an example of the concrete cutting process using the inclination cutter of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cosmetic frame 1a Center part 100 Slide base 101 Engagement part 110 Base part 120 Inclination part 130 Slot 131 Engagement recessed part 131a Inclined surface 131b Upright surface 132 Engagement recessed part 132a Inclined surface 132b Upright surface 133 Engagement recessed part 133a Inclined surface 133b Upright Surface 150 Blade holder 150a, 150b Inclined cam surface 152 Engagement part 155 Engagement hole 156 Protrusion 160 Spring 170 Slide operation part 170a, 170b Inclined cam surface 171 Slide operation part main body 172 Engagement part 173 Engagement hole 175 Engagement Hook 176 Operation plate 177 Engagement hook 178 Inclined surface 180 Engagement protrusion 180a Inclined surface 180b Upright surface 181 Inclined surface 188 Spring 200 Guide member 201 Guide groove 300 Blade 301 Blade tip 302 Engagement hole 400, 401

Claims (5)

An inclined cutter comprising: a slide base (100) that holds the blade (300) so that it can be inserted and removed; and a guide member (200) that engages with the slide base and guides the slide so as to reciprocate.
The slide table (100) includes a slot (130) extending inclined with respect to the slide surface, and a slide operation unit (170) that holds the blade (300) and is slidably mounted in the slot (130). ), And
The blade (300) is connected to the slide operation part (170) through the biasing member (160) so as to be relatively slidable in the extending direction of the slot (130). (160), the slide operation portion (170) is urged in a direction protruding outward from the slot (130),
The slide operation unit (170) includes a storage position in which the blade tip (301) is stored in the slot (130) even when the blade (300) is urged to the most protruding side by the urging member (160). When the blade (300) is urged to the most projecting side by the biasing member (160), the blade tip (301) is selectively positioned within the slot (130) so as to project from the slot (130) by a certain distance. An inclined cutter characterized by being fixed to An inclined cutter comprising a slide base (100) that holds the blade (300) so as to be able to be taken in and out, and is guided by the guide member (200) to reciprocate.
The slide table (100) includes a slot (130) extending inclined with respect to the slide surface, and a slide operation unit (170) that holds the blade (300) and is slidably mounted in the slot (130). ), And
The blade (300) is connected to the slide operation part (170) through the biasing member (160) so as to be relatively slidable in the extending direction of the slot (130). (160), the slide operation portion (170) is urged in a direction protruding outward from the slot (130),
The slide operation unit (170) includes a storage position in which the blade tip (301) is stored in the slot (130) even when the blade (300) is urged to the most protruding side by the urging member (160). When the blade (300) is urged to the most projecting side by the biasing member (160), the blade tip (301) is selectively positioned within the slot (130) so as to project from the slot (130) by a certain distance. An inclined cutter characterized by being fixed to   The inclined cutter according to claim 1 or 2, characterized in that the slide operation part (170) can be fixed to a plurality of projecting positions having different constant distances. The blade (300) is fixedly fixed to the blade holder (150), and is connected to the biasing member (160) via the blade holder (150).
The blade holder (150) and the slide operation unit (170) each include an inclined cam surface (150a, 150b, 170a, 170b), and the inclined cam surface (150a, 150b, 170a, 170b), and
Due to the cooperation between the inclined cam surfaces, the slide operating portion (170) and the blade holder (150) are pressed against the opposing wall surfaces in the slot (130), respectively, and thereby the blade in the slot (130). The inclined cutter according to claim 1 or 2, wherein rattling of (300) is prevented. The slide operation portion (170) includes an engagement protrusion (180) that elastically protrudes so as to be retractable, and the engagement protrusion (180) is provided on an engagement recess (131, 132, 133) provided on the side surface of the slot. ) Is fixed to the storage position or the protruding position,
The engaging recess is an upright surface (131a, 132a, 133a) whose front side surface in the blade sliding direction is inclined with respect to the sliding direction, while its rear side surface is substantially orthogonal to the sliding direction ( 131b, 132b, 133b)
The engagement protrusion (180) is also an upright surface (180a) whose front side surface in the blade slide direction is inclined with respect to the slide direction, while its rear side surface is substantially orthogonal to the slide direction ( 180b)
When an external force is applied to the slide operation part (170) in the forward direction, the engagement is achieved by the cooperation of the inclined surfaces (131a, 132a, 133a) of the engaging recess and the inclined surface (180a) of the engaging protrusion. The protrusion (180) is retracted to allow the slide operation part (170) to slide forward,
The slide operation part (170) and the engagement protrusion (180) have inclined surfaces (178, 181) that cooperate with each other, and when an external force is applied to the slide operation part (170) rearward. The engagement protrusion (180) is retracted by the cooperation of the inclined surfaces, and the slide operation part (170) is allowed to slide backward,
When an external force to the rear side directly acts on the blade (300), the upright surfaces (131b, 132b, 133b) of the engaging recesses and the upright surfaces (180b) of the engaging protrusions come into contact with each other. The inclined cutter according to claim 1, wherein the slide operation unit is prohibited from sliding backward.

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