JP2016156555A - Electric ice shaving machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric ice shaving machine which can be easily gripped and hardly broken even if being made to fall down.SOLUTION: An electric ice shaving machine 1 has a body 2 including an electric motor 4; a container 3 which is provided with a cutting blade 7 near a through-hole 6, and attached/detached to/from the body 2; an ice container 55 provided in the container 3; and a disc portion 5 which is a rotary portion rotated by the electric motor 4. The body 2 is provided with a narrowed portion 14 which has a thinner diameter than the maximum diameter portion 13A of the container 3, so that a user is enabled to easily use the machine by gripping the narrowed portion 14. Also, a diameter of the container 3 under the narrowed portion 14 can be made large, so that the amount of ice which can be stored in the container 3 is prevented from decreasing. In the inside of the narrowed portion 14, a detecting portion 61 for detecting the attaching/detaching state of the container 3 is provided, so that even if the ice in the container 3 melts while the electric ice shaving machine 1 falls down, water hardly enters the detecting portion 61.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electric ice shovel that can be used by being held by hand.

  Conventionally, this type of electric ice shovel has a main body with a built-in motor, a detachable attachment to the main body, and a slit for dropping ice cut by the cutter and the cutter. And a bottomed cylindrical container portion that can store ice, and a pressing portion that is rotated by the motor while pressing the ice against the cutter within the container portion (for example, patents) Reference 1). And by comprising in this way, the shaved ice can be directly arranged with respect to the desired location of containers, such as a dish.

Utility Model Registration No. 3180023

  Such an electric ice cutter is preferably formed in an elongated cylindrical shape so that it can be gripped by hand and used. However, if such an electric ice cutter is made too thin, there is a problem that the amount of ice that can be accommodated in the container portion is reduced. Moreover, since such an electric ice shovel is formed in an elongated cylindrical shape, there is no problem when it is used by being gripped by hand, but there is a possibility that it will fall down when placed on a table or the like. . And if this electric ice shovel is left falling down, ice will melt and water will be generated. In this type of electric ice shovel, a detection unit is provided in the main body so that the pressing unit does not rotate when the container unit is not attached, so that water flows into the main unit from the detection unit, and the main unit is There is a risk of failure.

  An object of the present invention is to solve the above-mentioned problems, and to provide an electric ice shovel that is easy to grip and hardly breaks down even if it falls down.

  The electric ice shovel according to claim 1 of the present invention includes a main body in which an electric motor is built in, a container provided with a through hole and having a cutting blade in the vicinity of the through hole, and a detachable container with respect to the main body. In the electric ice shovel having an ice container provided in the container and a rotating part rotated by the electric motor, the main body is provided with a constricted part that is more meridian than the maximum diameter part of the container. Is.

  According to a second aspect of the present invention, there is provided the electric ice shovel according to the first aspect, wherein a detection unit for detecting the attachment / detachment state of the container is provided inside the constricted unit.

  According to a third aspect of the present invention, there is provided the electric ice shovel according to the second aspect, wherein a lower wall through hole is provided in the lower wall portion of the main body, and the detection portion is provided through the lower wall through hole. At the same time, the distance from the virtual straight line simultaneously contacting the main body and the container to the lower wall through hole is made larger than the distance from the virtual straight line to the inner surface of the ice container.

  According to a fourth aspect of the present invention, there is provided an electric ice shovel according to the third aspect, wherein a weir portion is provided on the main body side of the container.

  Furthermore, the electric ice shovel according to claim 5 of the present invention is the one according to claim 3, wherein the weir portion is provided on the container side of the lower wall portion of the main body.

  By configuring the electric ice shovel according to claim 1 of the present invention as described above, the user can easily use the constricted portion by gripping the constricted portion, and lower than the constricted portion. Since the diameter of the container can be increased, the amount of ice that can be accommodated in the container can be kept small.

  In addition, even if the ice in the container is melted and water is generated in the state where the electric ice-shaker is collapsed, the water is generated even when the electric ice-shaker is collapsed by providing a detection unit that detects the attachment / detachment state of the container. Can be made difficult to enter the detector.

  In addition, a through hole is provided in the lower wall portion of the main body, the detection unit is provided through the through hole, and the distance from the virtual straight line simultaneously contacting the main body and the container to the through hole is By making the distance larger than the distance to the inner surface of the container, even if the ice in the container melts and water is generated in a state where the electric ice shovel has fallen, this water further enters the detection unit. It can be difficult.

  In addition, by providing a weir part on the main body side of the container, even if the ice in the container melts and water is generated in a state where the electric ice shovel is collapsed, the water is blocked by the weir part. Thus, it is possible to make it more difficult to enter the detection unit.

  Further, by providing a weir part on the container side of the lower wall part in the main body, even if the ice in the container melts and water is generated in a state where the electric ice shovel is collapsed, the water is It is blocked by the weir part, and can be made more difficult to enter the detection part.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing of the electric ice shovel which shows Example 1 of this invention. It is an expanded sectional view around the detection part. It is a perspective view of an electric ice shovel. It is a bottom view of the same electric ice shovel. FIG. 3 is a cross-sectional view of the electric ice shaker in a collapsed state. It is sectional drawing of the principal part of the electric ice shovel which shows Example 2 of this invention.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the accompanying drawings. The embodiments described below do not limit the contents of the present invention described in the claims. In addition, all of the configurations described below are not necessarily essential requirements of the present invention.

  Hereinafter, Example 1 of the present invention will be described with reference to FIGS. Reference numeral 1 denotes an electric ice shovel according to the present invention. The electric ice maker 1 includes an upper main body 2, a lower container 3 that can be attached to and detached from the main body 2, an electric motor 4 built in the main body 2, and a disk portion that is a rotating part that is rotated by the electric motor 4. 5, a through hole 6 provided in the main body 2, and a cutting blade 7 provided in the vicinity of the through hole 6. The main body 2 and the container 3 are made of synthetic resin or the like. Moreover, the center line of the main body 2 and the container 3 is located on a coaxial line.

  The main body 2 has an upper surface portion 12 formed of a curved surface 11 at an upper portion, and a main body cylindrical portion 13 at a lower portion of the upper surface portion 12, and the main body cylindrical portion 13 is located on an outer surface. The main body cylindrical portion 13 has a curved constricted portion 14 that is slightly narrower below the center in the height direction. The upper end of the main body cylindrical portion 13 is the maximum diameter portion 13A of the main body 2, and the lower end portion 13B of the main body cylindrical portion 13 is larger in diameter than the constricted portion 14 and smaller in diameter than the maximum diameter portion 13A.

  In the main body 2, horizontal plate-like upper and lower partition parts 15 and 16 are provided, and the lower part is closed by a lower wall part 17. The electric motor 4 is provided in the upper internal space 18 above the upper partition portion 15, and a reduction gear group 20 as a reduction mechanism is provided in the lower internal space 19 of the upper and lower partition portions 15, 16. 20, the drive gear 4A of the electric motor 4 meshes. Further, the drive transmission shaft 21 is pivotally supported by the upper and lower partition portions 15 and 16, and the lower end of the drive transmission shaft 21 protrudes from the lower portion of the lower partition portion 16.

  A rotating body 22 that rotates in the same body as the drive transmission shaft 21 is connected to the lower end of the drive transmission shaft 21. The rotating body 22 includes an upper rotating cylinder portion 23, a lower rotating shaft 24, and the disk portion 5 provided at the lower end of the rotating shaft 24. The lower wall portion 17 is provided with a bearing portion 25 that rotatably supports the rotating cylinder portion 23, and the bearing portion 25 has a short cylindrical shape. Further, the rotary cylinder portion 23 is provided with a sliding flange portion 26 that slides on the upper edge of the bearing portion 25, and the rotary cylinder portion 23 is formed into a lower wall portion by the bearing portion 25 and the sliding flange portion 26. 17 is rotatably supported.

  Further, a rotation transmission portion 21A is provided at the lower end of the drive transmission shaft 21, and the rotation of the drive transmission shaft 21 is transmitted to the rotary cylinder portion 23 of the rotating body 22 by the rotation transmission portion 21A. A plate-like partition part 27 is provided at the lower part of the rotating cylinder part 23, a through hole 28 is formed in the partition part 27, and a guide cylinder part 29 is formed below the partition part 27 continuously to the through hole 28. Is provided. Then, the upper part of the rotary shaft 24 is inserted into the through hole 28 and the guide tube part 29, and a retaining pin 30 as a retaining part is provided on the upper part of the rotating shaft 24.

  Further, a compression coil spring 31 as an urging means is disposed between the partition portion 27 and the disk portion 5, and the rotation shaft 24 and the disk portion 5 are moved downward with respect to the rotary cylinder portion 23 by the compression coil spring 31. Energized. The retaining pin 30 is a rotation transmitting portion, and the retaining pin 30 engages with a vertical groove (not shown) provided on the inner surface of the rotating cylinder portion 23 to rotate the rotation cylinder portion 23. It is transmitted to the shaft 24. Further, the retaining pin 30 can be moved up and down along the vertical groove, and the compression coil spring 31 is compressed, so that the rotary shaft 24 and the disk portion 5 can be raised.

  A push button type drive switch 32 is provided on the upper side surface of the main body cylindrical portion 13, and the motor 4 can be turned on and off by operating and driving the drive switch 32. 4 is connected to a household power source by a power cord 4B and is driven by the household power source. The drive switch 32 is urged outward by a compression coil spring 33 as urging means, and protrudes outward from the outer periphery of the main body cylindrical portion 13 even during on / off.

  The disk portion 5 has a pressing surface 34 for making contact with ice on the lower surface, and the pressing surface 34 has a plurality of claw portions 35 for strengthening the catching with ice. Yes.

  The container 3 has a container cylindrical portion 41 on the outer surface, and the container cylindrical portion 41 is substantially cylindrical and has a shape that decreases in a curved shape toward the upper side. It becomes flush with the outer surface of the lower end portion 13B of the main body cylindrical portion 13. The main body 2 and the container 3 are detachably assembled by a bayonet coupling structure 42.

  Specifically, a ring-shaped dam portion 43 is provided inside the upper end portion 41A of the container cylindrical portion 41, and the container inner cylindrical portion 44 is provided to project upward from the inner end of the dam portion 43, while the main body cylinder A main body inner cylinder part 45 is provided in the lower part of the shape part 13, and the container inner cylinder part 44 and the main body inner cylinder part 45 have substantially the same cross section over the entire length. In this example, the dam portion 43 is arranged on the main body 2 side of the container 3.

  A plurality of bayonet protrusions 46 are provided at equal intervals in the circumferential direction on the outer periphery of the upper end of the container inner cylinder portion 44, and the inner periphery of the main body inner cylinder portion 45 corresponds to the bayonet protrusion 46. A bayonet groove 47 is provided. The bayonet groove 47 communicates with a groove inlet (not shown) that opens at the lower edge of the main body inner cylinder portion 45, and extends circumferentially along the outer periphery of the main body inner cylinder portion 45. An extending locking groove (not shown) is provided.

  Then, the bayonet protrusion 46 is inserted into the groove inlet so that the container inner cylinder portion 44 is inserted into the main body inner cylinder portion 45, and the container 3 is rotated in the extending direction of the locking groove portion. As a result, the bayonet protrusion 46 is locked in the locking groove portion of the bayonet groove 47. Thereby, the container 3 and the main body 2 are coupled. Further, the container 3 can be removed from the main body 2 by rotating it in the reverse direction.

  The lower portion of the container tubular portion 41 is closed by a bottom surface portion 51, the through hole 6 is provided in the bottom surface portion 51, and the cutting blade 7 is provided in the lower portion of the bottom surface portion 51. The blade portion faces the bottom surface portion 51 from the through hole 6. Further, a rotary knob 52 for adjusting the position of the cutting blade 7 is provided, and by operating this knob 52, the protruding amount on the bottom surface portion 51 of the cutting blade 7 can be adjusted.

  Further, a seating cylinder part 53 is provided at the lower part of the container tubular part 41, and a ring protector 54 made of an elastic material is provided on the outer periphery of the seating cylinder part 53, and the seating cylinder part 53 is provided by the ring protector 54. Is protecting. The ring protector 54 is integrally provided with a ring portion 54 </ b> A covering the outer periphery of the seating tube portion 53 and a bottom surface portion 54 </ b> B provided on the bottom surface of the seating tube portion 53. The maximum diameter portion 54C on the outer periphery of the ring portion 54A of the ring protector 54 is formed larger than the outer periphery of the lower portion of the container cylindrical portion 41.

  A cylindrical ice container 55 is provided in the container 3, the bottom part of the ice container 55 is provided on the bottom part 51, and the disk part 5 is loosely inserted therein. A gap 56 is provided between the outer periphery of the ice container 55 and the inner periphery of the container cylindrical portion 41.

  A detection unit 61 that detects the attachment / detachment state of the container 3 is provided inside the constricted unit 14. Specifically, the main body 2 is provided with a switch storage chamber 62 below the lower partition portion 16, and the switch storage chamber 62 includes a side surface portion 62A that surrounds the four sides and a lower surface portion that blocks the lower portion of the side surface portion 62A. 62B and a detection switch 63 is disposed inside.

  The detection unit 61 is an operator of the detection switch 63 and is disposed on the same side as the drive switch 32 with respect to the center of the main body 2. Further, the detection unit 61 includes a base end portion 64 inserted through the through hole 62C formed in the lower surface portion 62B, and a distal end portion 65 inserted through the lower wall through hole 17A formed in the lower wall portion 17. The proximal end portion 64 and the distal end portion 65 are in an eccentric position in a plane, and the axial center of the proximal end portion 64 is on the center side, and the center of the distal end portion 65 is on the outer side. The distal end portion 65 is provided with a compression coil spring 66 as an urging means. The compression coil spring 66 is disposed between the lower surface portion 62B and the distal end portion 65, and urges the detection portion 61 downward. doing. Further, a retaining portion 67 having a diameter larger than that of the through hole 62C is provided at the base end of the detecting portion 61, and the retaining portion 67 is attached by a screw 67A screwed to the base end portion 64. The screw 67A itself may integrally have a flange-shaped retaining portion 67.

  An upper edge 68 serving as a contact portion is provided above the container inner cylinder portion 44 at the upper portion of the container 3, and when the bayonet coupling structure 42 is coupled, the upper edge 68 is moved to the detection unit. When the tip portion 65 of 61 is pushed up and the detection portion 61 moves upward against the bias of the compression coil spring 66, the detection switch 63 is turned on, and it can be detected that the container 3 is attached to the main body 2. When the tip 65 is not pushed, the detection switch 63 is turned off, and it is detected that the container 3 has been removed from the main body 2.

  Then, the motor 4 can be driven by the drive switch 32 on condition that the detection switch 63 is turned on, and the motor 4 is driven even if the drive switch 32 is operated when the detection switch 63 is turned off. do not do. That is, power is supplied to the electric motor 4 on condition that the detection switch 63 is on, and no electric power is supplied to the electric motor 4 when the detection switch 63 is off. Further, the electric motor 4 may be configured to be driven in a state where the drive switch 32 is pressed, and to stop driving the electric motor 4 when it is released and stopped.

  As shown in FIG. 1 and the like, the detection switch 63 and the detection unit 61 are arranged on one side in the diameter direction with respect to the center of the main body 2. Further, as shown in FIG. 5, in a plane including the center of the main body 2 and the container 3 and the center of the distal end portion 65 of the detection unit 61, the imaginary straight line K on the outer surface side of the main body 2 and the container 3 contacts the diametrical side K The distance L to the lower wall through-hole 17A is made larger than the distance L1 to the virtual straight line K and the inner surface 55N of the ice container 55. In addition, when the virtual straight line K and the inner surface 55N are not parallel, the distance L1 to the upper end position of the inner surface 55N can be used. Furthermore, the distance L2 from the virtual straight line K to the inner end of the dam portion 43 is larger than the distance L.

  The electric ice shovel 1 includes a pedestal 71 made of a synthetic resin or the like as a separate body. The pedestal 71 has a flat circular bottom surface 72, a cylindrical inner wall portion 73 erected from the periphery of the bottom surface portion 72, a ring-shaped connecting portion 74 provided around the inner wall portion 73 and the upper end thereof, The outer wall portion 75 is provided integrally with an outer wall portion 75 that hangs downward from the connecting portion 74, and a lower portion of the outer wall portion 75 is curved so as to expand downward. A plurality of leg portions 76 are provided below the bottom surface portion 72.

  The inner wall 73 has an inner diameter substantially equal to the maximum diameter 54C of the ring protector 54, and the lower portion of the container 3 is detachably fitted in the inner wall 73 of the pedestal 71 so that The lower surface of the seating cylinder portion 53 is placed on. Thus, by using the pedestal 71 that is larger than the seating cylinder portion 53, the electric ice shovel 1 can be stably set up, and further, dust and the like can be prevented from entering the through-hole 6, and ice ice can be prevented. Even if water generated in the container 55 falls from the through hole 6, it is possible to prevent the water from being received by the pedestal body 71 and leaking to the outside.

  Next, a method for using the electric ice cutter 1 will be described. The main body 2 and the container 3 are separated, and ice (not shown) is put into the ice container 55 in the container 3 from the upper opening 44 </ b> A of the container inner cylinder part 44. In a state before the container 3 is attached, the distal end portion 65 of the detection unit 61 protrudes downward from the lower wall through hole 17A due to the urging of the compression coil spring 66, and the detection unit 61 does not detect the container 3, so that the drive switch 32 Even if is operated, the electric motor 4 is not driven. The upper opening 44A is formed by an inner peripheral surface of the container inner cylinder portion 44, and the inner diameter of the ice container 55 is larger than the diameter of the upper opening 44A.

  After putting ice in the ice container 55, the main body 2 is attached to the container 3. In this case, when the disk part 5 is inserted into the ice container 55 through the upper opening 44 </ b> A and the disk part 5 hits the ice, the compression coil spring 31 contracts, and the rotary shaft 24 and the disk part 5 rise with respect to the main body 2. . When the main body 2 is attached to the container 3 by the bayonet coupling structure 42, the upper edge portion 68 of the container 3 pushes the lower end of the tip portion 65, the detection portion 61 is pushed up, and the container 3 is attached to the main body 2. Is detected by the detection switch 63.

  When the detection switch 63 detects that the container 3 is attached to the main body 2, the electric motor 4 can be driven by operating the drive switch 32. In this state, when the user grips the main body 2 and operates the drive switch 32, the electric motor 4 rotates, and this rotation is decelerated by the reduction gear group 20, and the disk portion 5 rotates. The ice in the ice container 55 is pressed and rotated by the rotation of 5, and the ice is scraped by the cutting blade 7 and falls from the through hole 6. The user can grip the constricted portion 14 that is formed thin in the main body 2 and is easy to grip.

  Moreover, it can stand stably using the base body 71 except at the time of use. On the other hand, even if the electric ice shovel 1 is turned down and the water in the ice container 55 melts and water is not noticed as shown in FIG. A detecting portion 61 provided in the hole 17A is provided in the constricted portion 14, and the distance L from the virtual straight line K (that is, the installation surface) where the main body 2 and the container 3 are in contact with each other at the time of falling to the lower wall through hole 17A is the virtual straight line K. (Ie, the installation surface) is larger than the distance L1 from the ice container 55 to the inner surface 55N, and the container 3 is further provided with a weir 43, and the distance from the virtual straight line K (ie, the installation surface) to the inner end of the weir 43 Since L2 is larger than the distance L, it is difficult for water to enter the lower wall through hole 17A.

  As described above, in the present embodiment, the main body 2 in which the electric motor 4 is incorporated, the through-hole 6 and the cutting blade 7 in the vicinity of the through-hole 6, and the container 3 detachable from the main body 2, In an electric ice shovel 1 having an ice container 55 provided in the container 3 and a disk part 5 which is a rotating part rotated by the electric motor 4, the main body 2 is thinner than the maximum diameter part 13A of the container 3. Since the constricted portion 14 serving as a warp is provided, the user can easily use the constricted portion 14 by gripping the constricted portion 14, and the diameter of the container 3 below the constricted portion 14 can be increased. The amount of ice that can be stored in the container 3 can be kept small.

  Moreover, since the detection part 61 which detects the attachment or detachment state of the container 3 was provided in the inside of the constriction part 14, even if the ice in the container 3 melts | dissolves and water arises in the state where the electric ice shovel 1 fell down, this It is possible to make it difficult for water to enter the detection unit 61.

  Further, a lower wall through-hole 17A is provided in the lower wall portion 17 of the main body 2, and a detection unit 61 is provided through the lower wall through-hole 17A, and the lower wall penetrating from the virtual straight line K that contacts the main body 2 and the container 3 simultaneously. Since the distance L to the hole 17A is larger than the distance L1 from the imaginary straight line K to the inner surface 55N of the ice container 55, the ice in the container 3 melts and the water is melted in the state where the electric ice shovel 1 is tilted. Even if it occurs, this water can be made more difficult to enter the detection unit 61.

  Further, since the weir part 43 is provided on the main body 2 side of the container 3, even if the ice in the container 3 melts and water is generated in the state where the electric ice shovel 1 is collapsed, the water is blocked by the weir part 43. As a result, the detection unit 61 can make it harder to enter.

  Hereinafter, since the maximum diameter portion of the container 3 is larger than the maximum diameter portion of the main body 2 as an effect on the embodiment, the volume efficiency of the container 3 is excellent. In addition, since the constricted portion 14 is located above the center in the height direction of the electric ice shovel 1, the drive switch 32 can be operated using the thumb while the constricted portion 14 is held with one hand. Further, since the power cord 4B is provided above the position of the constricted portion 14 of the main body 2, the power cord 4B does not hit a dish or the like that receives scraped ice. Further, since a gap 56 is provided between the outer periphery of the ice container 55 and the inner periphery of the container cylindrical portion 41, the water inside the ice container 55 is retained in the gap 56 even if the electric ice shovel 1 falls down. It becomes difficult to flow and enter the lower wall through hole 17A side. The gap 56 is preferably 10 mm or more in the diameter direction, and the space 56 can be secured by providing the constricted portion 14. In addition, by providing the pedestal body 71 as a separate body, the electric ice shovel 1 can be stably set up, and dust and the like can be prevented from entering from the through hole 6, and in the ice container 55. Even if the generated water falls from the through hole 6, this water can be received by the pedestal 71. Furthermore, since the inner diameter of the ice container 55 is larger than the diameter of the upper opening 44A, more ice can be stored than in the conventional case.

  FIG. 6 shows a second embodiment. The same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. In the second embodiment, the container 3 is lower and the main body 2 is formed higher than the first embodiment, and the dam portion 43 is provided on the main body 2 on the container 3 side.

  Further, an inner step portion 81 is provided at the upper end portion 41A of the container cylindrical portion, and a container inner tube portion 44 is projected from the inner end of the inner step portion 81. A plurality of bayonet protrusions 46 are provided at equal intervals in the circumferential direction. On the other hand, a bayonet groove 47 is provided on the inner periphery of the lower end portion 13 </ b> B of the main body cylindrical portion 13 corresponding to the bayonet protrusion 46.

  A cylindrical portion 82 is projected from the upper portion of the dam portion 43, a guide shaft 83 is inserted into the cylindrical portion 82, and a transmission member 84 is connected to the lower end of the guide shaft 83. The transmission member 84 integrally includes a horizontal side 85 and a vertical side 86. The guide shaft 83 is integrally formed on the upper surface of the lateral side 85. The guide shaft 83 is in contact with a detection unit (not shown) that is inserted through the lower wall through hole 17A and protrudes downward. Further, the lower end 86A of the vertical side 86 is disposed along the inner surface of the main body cylindrical portion 13, and when the container 3 is attached to the main body 2, the upper edge portion 44B of the inner cylinder portion 44 is provided. Abut. A compression coil spring 87 as an urging means is disposed between the cylindrical portion 82 and the lateral side 85, and the transmission member 84 is urged downward by the compression coil spring 87. Further, a reinforcing rib 88 that connects the lower surface of the horizontal side 85 and the inner surface of the vertical side 86 is provided on the transmission member 84.

  At the upper part of the guide shaft 83, a retaining portion 67 is provided by a screw 67A. The screw 67A itself may integrally have a flange-shaped retaining portion 67. The lower wall portion 17 is provided with a through hole 17B for inserting the head of the screw 67A.

  The position where the retaining portion 67 contacts the lower surface of the lower wall portion 17 is the upper limit position of the transmission member 84, and conversely, the position where the retaining portion 67 contacts the upper surface of the cylindrical portion 82 is the position of the transmission member 84. It is the lower limit position.

  In use, as shown in FIG. 6, when the container 3 is attached to the main body 2, the upper edge part 44 </ b> B of the container inner cylinder part 44 pushes up the lower end part 86 </ b> A of the vertical side 86, the compression coil spring 87 contracts, and the transmission member 84. At the same time, a detection unit (not shown) is pushed up, and the detection switch 63 detects that the container 3 is attached to the main body 2.

  On the other hand, when the container 3 is detached from the main body 2, the detection unit is lowered together with the transmission member 84 by the compression coil spring 87 and the biasing means (not shown) for the detection unit, the detection switch 63 is turned off, and the container 3 is removed from the main body 2. Is detected.

  As described above, the present embodiment has the same operations and effects as the first embodiment.

  Furthermore, in this embodiment, since the weir part 43 is provided on the container 3 side of the lower wall part 17 in the main body 2, the ice in the container 3 is melted and water is generated in the state where the electric ice shovel 1 is tilted. However, this water can be blocked by the dam portion 43 so that it is more difficult to enter the detection portion 61.

  In addition, this invention is not limited to the above Example, A various deformation | transformation implementation is possible within the range of the summary of invention. For example, in the above embodiment, the ring-shaped weir portion is shown, but the weir portion may be provided only on the detection portion side. Moreover, although what used household power supply was shown in the Example, a battery is good also as a power supply.

DESCRIPTION OF SYMBOLS 1 Electric ice shovel 2 Main body 3 Container 4 Electric motor 5 Disk part (rotating part)
6 Through-hole 7 Cutting blade 14 Constricted part 17 Lower wall part 17A Lower wall through-hole 54C Maximum diameter part 55 Ice container 61 Detection part 65 Tip part K Virtual straight line L Distance L1 Distance

Claims (5)

A main body with a built-in electric motor, a through-hole provided and a cutting blade in the vicinity of the through-hole, a detachable container with respect to the main body, an ice container provided in the container, and the electric motor In an electric ice shovel having a rotating part to be rotated,
An electric ice shovel, wherein the main body is provided with a constricted portion that is more meridian than the maximum diameter portion of the container. The electric ice shovel according to claim 1, wherein a detection unit that detects the attachment / detachment state of the container is provided inside the constriction unit. A lower wall through hole is provided in the lower wall portion of the main body, the detection unit is provided through the lower wall through hole,
3. The electric ice according to claim 2, wherein a distance from an imaginary straight line simultaneously contacting the main body and the container to the lower wall through hole is larger than a distance from the imaginary straight line to an inner surface of the ice container. Scraper. The electric ice shovel according to claim 3, wherein a weir portion is provided on the main body side of the container. 4. The electric ice shovel according to claim 3, wherein a weir portion is provided closer to the container than the lower wall portion of the main body.

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