JP2011069590A - Ice-making machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent collision between ice dropping down from a chill tray and an ice inspection member. <P>SOLUTION: The ice-making machine 1 includes: an ice separating means taking out ice from the chill tray 21 and making the ice drop down from a lateral side including a guide member 24 of the chill tray 21; an ice storage part 1a storing ice made drop down; and the ice inspection member 4 lifted/lowered within the ice storage part 1a during ice inspection for inspecting the amount of ice within the ice storage part 1a. The ice inspection member 4 is provided on the lateral side opposite to a side in which the ice in the chill tray 21 drops down, so as to prevent collision between the dropping ice and ice inspection member 4. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an ice making device having an automatic ice making function.

  As an ice making device having an automatic ice making function, for example, there is one disclosed in Patent Document 1.

JP 2008-267630 A

  The ice making device of Patent Document 1 is scraped by an ice making tray, a heater that heats the ice making tray to separate the ice from the ice making tray, a scraping member that rotates about one axis to scrape the ice from the ice tray, and a scraping member. An ice storage unit for storing ice falling from the ice tray, and an ice detecting member for detecting the height of ice stored in the ice storage unit.

  The ice detecting member is adapted to rotate around another rotating shaft parallel to the rotating shaft of the scraping member, and a radial arm extending radially from the rotating shaft and an ice tray from the tip of the radial arm. And an axial arm portion extending in the axial direction along the side surface.

Here, if the ice detecting member is positioned below the ice tray when the ice is dropped from the ice tray, the dropped ice may collide with the ice detecting member and the ice detecting member may be damaged.
Therefore, when dropping the ice from the ice tray, it is necessary to rotate the ice detecting member around the rotation axis and arrange the axial arm portion in the lateral direction of the ice tray.

In the ice making device of Patent Document 1, since the rotation shaft of the ice detecting member is provided on the ice falling side of the ice tray, the ice detecting member rotates on the ice falling side.
Therefore, in order to avoid collision with ice in a state where the ice detecting member is arranged in the lateral direction of the ice tray, the length of the radial arm portion is increased, and ice is placed between the axial arm portion and the ice tray. It is necessary to secure a space for passing through, and the ice making device is enlarged in the width direction.

  Therefore, it is required to make the ice making device compact while avoiding the collision between the ice detecting member and the ice.

The present invention provides an ice removing means for dropping ice from an ice tray from the side of the ice tray, an ice storage section for storing the dropped ice, and an ice storage section for inspecting the amount of ice in the ice storage section. In an ice making device that includes an ice detecting member that moves up and down, the ice detecting member is provided on the side of the ice tray opposite to the side on which the ice falls.
With this configuration, since the ice does not fall on the side where the ice detecting member is provided, it is possible to prevent the falling ice and the ice detecting member from colliding with each other and preventing the ice detecting member from being damaged, and the ice falling. It is not obstructed by the ice detecting member.

In addition, the ice detecting member is configured to move up and down by moving in the vertical direction with respect to the ice tray.
With this configuration, the ice detecting member does not move so as to wrap around the side of the ice tray, so there is no need to provide a space for ensuring the movement of the ice detecting member in the width direction of the ice making device. The size can be suppressed.

The ice removing means is provided with a heater for heating the ice tray, and the ice making device is provided in the ice making chamber with a gap between the ice making tray to which the heater is attached and the wall portion of the ice making chamber. The ice detecting member is arranged in the gap.
If comprised in this way, since the ice detection member can be provided using the clearance gap ensured when providing the ice tray with the heater attached in the ice making chamber, the size in the width direction of the ice making device can be suppressed. Can do.

The ice detecting member has an ice contact portion that extends to the lower side of the ice tray.
If comprised in this way, since an ice detection member comes to contact ice over a wide range, even if distribution of the height of the ice in an ice storage part is biased, ice can be detected.

The heater is attached to the lower surface of the ice tray, and the ice contact portion is formed in a shape that covers the heater from the lower side of the ice tray when the ice detecting member moves in the upward direction away from the ice storage portion. It was set as the composition.
With this configuration, the radiant heat of the heater does not directly reach the ice stored in the ice storage part by being blocked by the ice contact part. Therefore, it is possible to prevent the temperature in the ice making chamber from rapidly rising due to the heat of the heater.

  The ice making device can be made compact by suppressing the size of the ice making device in the width direction while avoiding contact between the falling ice and the ice detecting member.

It is a perspective view of the ice making device concerning an embodiment. It is an exploded perspective view of the ice making device concerning an embodiment. It is sectional drawing of an ice tray. It is a bottom view of an ice tray. It is the front view which abbreviate | omitted illustration of the water supply part of the ice making apparatus arrange | positioned in an ice making chamber. It is the side view which abbreviate | omitted illustration of the water supply part of the ice making apparatus arrange | positioned in an ice making chamber. They are the top view which removed the 1st case part and looked at the inside of a main-body part, and the top view of a cam gearwheel. It is sectional drawing of a main-body part. It is a perspective view which expands and shows the principal part of a drive unit. It is a flowchart which shows operation | movement of an ice making apparatus. It is a figure explaining operation | movement of an ice making apparatus. It is a perspective view of the ice making device concerning a modification.

Embodiments of the present invention will be described below.
FIG. 1 is a perspective view of an ice making device 1 according to an embodiment, where (a) is a view as seen from a guide member 24 side from which ice is discharged, and (b) is an ice detecting member on the opposite side. It is the perspective view seen from 4 side. FIG. 2 is an exploded perspective view of the ice making device 1 and is a view in which a part of the guide member 24 is cut away.

  As shown in FIGS. 1 and 2, an ice making device 1 according to an embodiment is arranged in an ice making chamber such as a refrigerator to continuously produce ice, and the produced ice is stored in an ice storage below the ice making device 1. The unit 1a has a function of automatically discharging, and these functions are realized by a combination of operations of the ice detecting mechanism and the switch mechanism provided in the drive unit 3.

The ice making device 1 includes an ice making unit 2 for producing ice, a drive unit 3, and an ice detecting member 4 for confirming the amount (height) of ice stored in the ice storage unit 1a.
The ice making unit 2 includes an ice tray 21, a water supply unit 22 for supplying water to the ice tray 21, a scraping member 23 for scraping ice in the ice tray 21, and ice scraped by the scraping member 23 in the ice tray 21. And a guide member 24 that drops from the side.

  3 is a cross-sectional view of the ice tray 21 cut along the plane A in FIG. 2, and FIG. 4 is a bottom view of the ice tray 21.

As shown in FIGS. 2 and 3, the ice tray 21 has a rectangular shape in a top view, and a plurality of ice making grooves 212 having openings exposed on the upper surface 21 a are provided along the longitudinal direction.
The ice making groove 212 has a semicircular cross-sectional shape in the width direction of the ice making tray 21, and the depth of the ice making groove 212 becomes shallower toward the partition plate 211.

Each of the partition plates 211 that define the ice making grooves 212 is provided with a notch 211a that allows the adjacent ice making grooves 212 to communicate with each other with the partition plate 211 interposed therebetween.
A water supply port 213 that guides water supplied from the water supply unit 22 into the ice tray 21 is provided on one side surface in the longitudinal direction of the ice tray 21 (the side surface opposite to the drive unit 3). The water supplied into the ice making groove 212 via 213 reaches all the ice making grooves 212 through the notches 211a.

  The ice making tray 21 is formed of an aluminum material that has been subjected to surface treatment such as coating or anodizing, and the water stored in each ice making groove 212 is cooled by being cooled in a refrigeration room. It is designed to freeze inside.

A bearing portion 214 that rotatably supports one end of the scraping member 23 is provided at a central portion in the width direction of the ice tray 21 at a position adjacent to the water supply port 213.
A bearing portion 217 that rotatably supports the other end side of the scraping member 23 is also provided at the central portion in the width direction on the side surface of the ice tray 21 on the drive unit 3 side.

On one of the long side surfaces of the ice tray 21, a wall portion 215 is provided so as to protrude upward from the upper surface 21 a of the ice tray 21.
The wall portion 215 is provided over the entire length in the longitudinal direction. When the scraping member 23 scrapes out the ice in the ice making groove 212, the side surface (ice detecting member) on which the guide member 24 is not provided. The side where 4 is located is prevented from falling.

Attachment portions 216 are integrally formed with the wall portion 215 on one end side and the other end side in the longitudinal direction of the wall portion 215.
As shown in FIG. 3, the mounting portion 216 has an L-shaped cross section including an extending portion 216 a that extends laterally from the upper end of the wall portion 215, and a fixing portion 216 b that extends upward from the tip of the extending portion 216 a. Reinforcing ribs 216c and 216d are provided on the upper surface and the lower surface of the extending portion 216a, respectively.
The ice tray 21 is arranged in a state where the fixing portion 216b is sandwiched between the fixing member 300 and the headed screw 301 in the ice making chamber.

As shown in FIG. 4, a U-shaped heater 25 is provided on the bottom surface of the ice tray 21 in a plan view.
The heater 25 is provided to heat the ice tray 21 when the ice is scraped from the ice tray 21 to melt the ice on the contact interface side with the ice tray 21 and to float the ice from the ice tray 21.

On the bottom surface of the ice tray 21, an outer rib 218 a having a shape matching the outer shape of the heater 25 (substantially U-shaped in plan view) and a position spaced inward from the outer rib 218 a along the longitudinal direction of the ice tray 21. An extending inner rib 218b and an engaging claw 219 that engages with the curved portion 25a of the heater 25 are provided. The heater 25 is sandwiched between the outer rib 218a, the inner rib 218b, and the engaging claw 219. It is provided in the state.
A connection terminal portion 251 is provided at one end and the other end in the longitudinal direction of the heater 25, and the connection terminal portion 251 protrudes from the side surface of the ice tray 21 on the drive unit 3 side.

As shown in FIGS. 1 and 2, the water supply unit 22 is disposed at the end of the ice making unit 2 opposite to the drive unit 3 so as to face the drive unit 3.
A water supply pipe (not shown) or a water supply tank (not shown) extending from the water supply pump is connected to the water supply unit 22, and water is supplied to the ice tray 21 through these. It is like that.

The scraping member 23 includes a rotation shaft 231 extending along the longitudinal direction of the ice tray 21 and a scraping portion 232 provided at predetermined intervals in the axial direction of the rotation shaft 231. The scraping portions 232 are provided in the same number as the ice making grooves 212 so as to correspond one-to-one with the ice making grooves 212 of the ice tray 21.
As shown in FIG. 5, the scraping portion 232 includes a plate-like contact portion 232 a extending in the tangential direction of the rotation shaft 231 as viewed from the axial direction, and a reinforcing rib 232 b that connects the contact portion 232 a and the rotation shaft 231. With.

  As shown in FIG. 2, a cylindrical reduced diameter portion 231a that is rotatably supported by a bearing portion 214 of the ice tray 21 is provided at the distal end of the rotating shaft 231, and a cam described later is provided at the proximal end. A connecting portion 231b connected to the connecting portion 43 of the gear 40 is formed in a D-shaped cross section.

As shown in FIGS. 1 and 2, the guide member 24 is provided to guide the ice scraped from the ice tray 21 by the scraping member 23 to the side of the ice tray 21.
The guide member 24 includes a side plate portion 241 that covers the side of the ice tray 21 on which the ice is discharged over the entire length in the longitudinal direction, and an inclined plate that extends from the upper end of the side plate portion 241 toward the scraping member 23 side. Unit 242.

The inclined plate portion 242 is provided so as to cover the upper surface of the ice tray 21 on the side where the ice is discharged over the entire length in the longitudinal direction.
The inclined plate portion 242 is inclined to the side plate portion 241 side, and the ice scraped from the ice tray 21 by the scraping member 23 slides on the upper surface of the inclined plate portion 242 to store ice from the side surface on the side plate portion 241 side. It falls to the part 1a.

The inclined plate part 242 is provided with notches 242a for avoiding interference with the scraping part 232 of the scraping member 23 at predetermined intervals along the longitudinal direction.
A slight inclination that inclines toward the notch 242a is provided on the upper surface of the inclined plate portion 242 in order to reduce the contact area with ice.

  FIG. 5 is a front view of the ice making device 1 arranged in the ice making chamber, in which the water supply unit 22 is not shown, and FIG. 6 is a right side view of the ice making device 1 arranged in the ice making chamber. .

As shown in FIGS. 5 and 6, the ice detecting member 4 is a lever-like member provided on the side surface of the drive unit 3. The ice detecting member 4 is provided for detecting the height of the ice stored in the ice storage unit 1a, and moves up and down in the ice storage unit 1a when detecting the amount of ice in the ice storage unit 1a. It has become.
The ice detecting member 4 is located on the side opposite to the guide member 24 so that the ice Ic falling toward the ice storage portion 1a does not collide with the ice detecting member 4.

The ice detecting member 4 includes a connecting portion 4a connected in an axial direction to an ice detecting shaft 60 to be described later of the drive unit 3, a base portion 4b extending in the radial direction from the connecting portion 4a, and ice contacting the ice in the ice storage portion 1a. A contact portion 4c.
As shown in FIG. 5, the ice detecting member 4 is disposed below the attachment portion 216 in a state where the ice making device 1 is attached to the fixing member 300, and a width W between the ice tray 21 and the fixing member 300. It is located in the gap.
As shown in FIG. 6, the ice detecting member 4 has a tip provided with an ice contact portion 4 c by rotating the connecting portion 4 a together with the ice detecting shaft 60 around the rotation axis X <b> 2 extending in the width direction of the ice tray 21. The side moves in the vertical direction (vertical direction) with reference to the ice tray 21.

  The ice contact portion 4c is provided to be inclined with respect to the base portion 4b, and when the ice detecting member 4 is disposed at a position (ice making position) indicated by a virtual line in FIG. 6, the base portion 4b is disposed horizontally. Thus, the ice contact portion 4c is arranged with the tip 4c5 side positioned upward.

  The ice contact portion 4c has an H-shaped cross section, and the lower plate portion 4c1 located on the lower side of the ice tray 21 is provided on the opposite side in order to increase the contact area with the ice in the ice storage portion 1a. It is formed wider than the upper plate part 4c2. Reinforcing ribs 4c4 are provided on both sides of the wall 4c3 connecting the lower plate 4c1 and the upper plate 4c2.

  As shown in FIG. 2, the drive unit 3 includes a main body portion 3a and a cover portion 3b attached to the main body portion 3a from the ice making unit 2 side, and detects the height of ice in the ice storage portion 1a. For this purpose, an ice detecting mechanism for moving the ice detecting member 4 up and down and a switch mechanism for determining whether or not to discharge ice to the ice storage portion 1a are provided.

FIG. 7A is a plan view of the inside of the main body portion 3a as viewed from the side opposite to the cover portion 3b with the first case portion 31 removed, and FIG. 7B is a cam gear in FIG. It is the top view which took out and showed 40. FIG.
8A is a diagram illustrating a cross section of the main body 3a taken along the line AA in FIG. 7A together with the first case portion 31, and FIG. 8B is a diagram illustrating the cam gear 40. It is the figure which showed the case where an angular position differs from (a).

  As shown in FIG. 7A, in the main body 3a, a cam gear 40, a motor M, and a motor are provided in a housing (see FIG. 2) including a first case portion 31 and a second case portion 32. A reduction gear train 50 that transmits the rotational output of M to the cam gear 40 and an ice detecting shaft 60 that is connected to the ice detecting member 4 are provided.

A worm 51 is connected to the output shaft of the motor (DC motor) M, and the worm 51 meshes with a first gear 52 constituting the reduction gear train 50.
The reduction gear train 50 includes a first gear 52, a second gear 53, and a third gear 54, and the rotational output of the motor M input to the first gear 52 via the worm 51 is It is transmitted to the cam gear 40 via the second gear 53 and the third gear 54.
The gears 52 to 54 of the reduction gear train 50 are rotatably supported by bearing portions (not shown) provided inside the first case portion 31 and the second case portion 32.

  As shown in FIG. 8A, a ring-shaped recess 42 is provided on the outer peripheral side when viewed from the axial direction on the second case portion 32 side of the cam gear 40, and on the inner side of the recess 42. A connecting portion 43 with the scraping member 23 is provided so as to protrude to the second case portion 32 side.

  The distal end portion 431 of the connecting portion 43 is formed with an outer diameter R1 aligned with the central insertion hole 3b1 of the cover portion 3b (see FIG. 2). In the state where the drive unit 3 is assembled, the distal end portion 431 is It is rotatably supported by the insertion hole 3b1 of the cover part 3b.

The base end portion 432 of the connecting portion 43 is formed with an outer diameter R <b> 2 that aligns with the insertion hole 321 provided in the center of the second case portion 32.
The connecting portion 43 passes through the second case portion 32 in a state where the first case portion 31 and the second case portion 32 are assembled, and the base end portion 432 is inserted through the insertion hole 321 of the second case portion 32. It is designed to be supported in a rotatable manner.

A bottomed hole 433 extending in the axial direction of the rotation axis X1 of the cam gear 40 is formed at the center of the connecting portion 43. The bottom portion 433a of the bottomed hole 433 is a second case than the bottom portion 42a of the recess 42. It is located on the part 32 side.
A wall portion 434 is provided in the bottomed hole 433 along the axial direction, and a section where the wall portion 434 is provided is aligned with the connecting portion 231b of the scraping member 23 (cross-section D shape). It is said that.
This is because the scraping member 23 and the cam gear 40 can be coupled so as to be integrally rotatable only by inserting the connecting portion 231b of the scraping member 23 into the bottomed hole 433 from the axial direction.

  A plurality of triangular reinforcing ribs 435 (see FIG. 2) having a triangular shape in a side view are provided on the outer periphery of the distal end portion 431 at predetermined intervals along the circumferential direction. The reinforcing ribs 435 are arranged radially around the rotation axis X <b> 1 and are provided in contact with the distal end portion 431 and the proximal end portion 432.

As shown in FIG. 8A, a cylindrical portion 44 is provided at the center of the surface of the cam gear 40 on the first case portion 31 side.
The cylindrical portion 44 extends in the direction opposite to the connecting portion 43 along the rotation axis X1, and the distal end portion 44a is externally fitted to the shaft portion 311 of the first case portion 31 and is rotatably supported.

  The cylindrical portion 44 is provided coaxially with the connecting portion 43 on the opposite side, and the base end portion 432 of the connecting portion 43 is rotatably supported by the insertion hole 321 of the second case portion 32 as described above. Therefore, when the rotation of the motor M is input to the cam gear 40 via the reduction gear train 50, the cam gear 40 rotates in one direction around the rotation axis X1 determined according to the rotation direction of the motor M. It has become.

  On the surface of the cam gear 40 on the first case portion 31 side, a ring-shaped inner concave portion 45 surrounding the cylindrical portion 44 and an outer concave portion 46 surrounding the inner concave portion 45 are provided.

The depth D1 of the inner recess 45 is deeper than the depth D2 of the outer recess 46, and the bottom portion 45a of the inner recess 45 is more than the bottom portion 433a of the bottomed hole 433 of the connecting portion 43. Located on the side.
The outer recessed portion 46 is provided at a position substantially aligned with the recessed portion 42 on the second case portion 32 side, and a part of the outer recessed portion 46 includes the first case portion 31 side of the cam gear 40 and the second case portion. A communication port 47 communicating with the 32 side is provided.

As shown in FIG. 7 (b), the communication port 47 has a part of the outer recess 46 radially outward at a position where a part of the arc wall 48 that partitions the inner recess 45 and the outer recess 46 is cut out. As it goes, it is cut out into a shape in which the circumferential width W1 becomes narrower.
Out of the edge portions 471 to 474 surrounding the communication port 47, the outer diameter side edge portion 473 has a shape drawing an arc whose distance from the rotation axis (center) X1 is r1, and the inner diameter side edge portion. 474 has a shape that draws an arc whose distance from the rotation axis (center) X1 is the same as the distance r2 to the outer periphery 481 of the arc wall 48.
One edge 471 and the other edge 472 in the circumferential direction around the rotation axis (center) X1 are symmetrical with respect to a straight line Lx passing through the rotation axis (center) X1 and the center in the circumferential direction of the edge 474. positioned.

  One end 48 a and the other end 48 b of the arc wall 48 that are in contact with the communication port 47 are bent along the edges 471 and 472 of the communication port 47 and slightly protrude radially outward.

The inner circumference 482 of the arc wall 48 and the edge portions 471, 472, 473 of the communication port 47 become cam surfaces on which the contact portion 642 of the ice detecting shaft 60 described later slides when the cam gear 40 rotates. The angle position around the rotation axis X2 of the ice detecting shaft 60 of the ice detecting mechanism to be described later and the position of the ice detecting member 4 are determined according to the cam surface on which the contact portion 642 slides. .
In the following description, the inner periphery 482 of the arc wall 48 and the edges 471, 472, 473 of the communication port 47 are denoted as cam surfaces 482, 471, 472, 473 as necessary.

The outer peripheral wall 461 of the outer recess 46 includes peripheral wall portions 461a and 461c whose distance from the rotation axis (center) X of the cam gear 40 is r3, and peripheral wall portions 461b and 461d whose distance is r4. The circumferential length of the portion 461b is set longer than the circumferential length of the circumferential wall portion 461d.
These peripheral wall portions 461a, 461b, 461c, and 461d are cam surfaces on which a contact portion 82a of a switch pressing lever 80 described later slides when the cam gear 40 rotates, and the contact portion 82a contacts. Depending on the cam surface, a switch pressing lever 80 of a switch mechanism, which will be described later, is driven in a direction to turn on or turn off the tact switch 90.
In the following description, the peripheral wall portions 461a to 461d are described as cam surfaces 461a to 461d as necessary.

FIG. 9 is an enlarged perspective view showing the main part of the drive unit 3, and is a view for explaining the configuration of the ice detecting mechanism and the switch mechanism.
The ice detecting mechanism includes cam surfaces 482 and 471 to 473 (see FIG. 7B) of the cam gear 40 and an ice detecting shaft 60 having a sliding portion 64 that slides on the cam surfaces 482 and 471 to 473. A coil spring 70 for urging the ice detecting shaft 60 in the rotational direction in which the contact portion 642 of the sliding portion 64 contacts the cam surface, and the ice detecting member 4 connected to the connecting portion 62 of the ice detecting shaft 60 (FIG. 1). Reference).

The ice detection shaft 60 is a shaft-like member that is provided through the mating surface of the first case portion 31 and the second case portion 32.
As shown in FIG. 7A, one end side of the ice detecting shaft 60 where the connecting portion 62 is provided is rotatably supported by a bearing portion 323 of the second case portion 32. The shaft portion 63 on the other end side provided with the sliding portion 64 is rotatably supported by a bearing portion (not shown) of the first case portion 31.
The ice detecting shaft 60 is configured to be rotatable around the rotation axis X2 in a state where the connecting portion 62 is disposed outside the second case portion 32, and in conjunction with the rotation of the ice detecting shaft 60, the ice detecting member The tip side where the 4 ice contact portions 4c are provided moves in the vertical direction of the ice tray 21 (see FIG. 6).

  As shown in FIG. 9, the ice detecting shaft 60 is provided with a sliding portion 64, a spring engaging portion 65, and a switch pressing prevention portion 67 in order from the shaft portion 63 side.

As shown in FIG. 8A, the sliding portion 64 has a protruding portion 641 extending in the tangential direction from the outer periphery of the main body portion 61 of the ice detecting shaft 60, and the protruding portion 641 side of the main body portion 61. A contact portion 642 that contacts the cam surfaces 482 and 471 to 473 of the cam gear 40 is provided on this surface.
The contact portion 642 is provided with contact surfaces 642a and 642b that are inclined to each other, and one of the contact surfaces 642a and 642b corresponds to the angular position around the rotation axis X1 of the cam gear 40. The cam surfaces 482 and 471 to 473 come into contact with each other.

When the angular position of the cam gear 40 is the position shown in FIG. 8A, the contact portion 642 is located in the communication port 47, and the contact surface 642b is in contact with the cam surface 473.
Further, when the angular position of the cam gear 40 is the position shown in FIG. 8B, the contact portion 642 is located in the inner recess 45, and the contact surface 642a is brought into contact with the cam surface 472. Yes.

As shown in FIG. 9, the spring engaging portion 65 extends from the outer periphery of the main body portion 61 to the first case portion 31 side (the side opposite to the contact portion 642 of the sliding portion 64) along the tangential direction. Is provided.
A coil spring 70 having one end supported by a first case portion 31 (not shown) is engaged with the engagement portion 65a of the spring engagement portion 65, and the ice detecting shaft 60 is connected to the rotation axis of the spring engagement portion 65. A force in the direction of rotating clockwise around X2 acts from the coil spring 70.

  Therefore, the abutting portion 642 of the sliding portion 64 located on the opposite side of the spring engaging portion 65 causes the cam surfaces 482 and 471 to 473 of the cam gear 40 (see FIG. 7B) due to the biasing force of the coil spring 70. It is maintained in the state pressed against (see).

In the embodiment, when the cam gear 40 rotates around the rotation axis X1, the contact surface 642a is the cam surface while the contact portion 642 slides on the cam surface 482 (see FIG. 7B). The contact surface 642b contacts the cam surface 473 while the contact portion 642 slides on the cam surface 473.
In addition, while the contact part 642 slides on the cam surfaces 471 and 472, the contact surface that contacts the cam surfaces 471 and 472 is switched between the contact surface 642a and the contact surface 642b. Yes.

The switch pressing prevention portion 67 is a plate-like member that constitutes a part of a switch mechanism described later, and is provided to extend radially outward from the outer periphery of the main body portion 61.
As shown in FIGS. 7A and 9, the switch pressing prevention portion 67 has an angular position of the ice detecting shaft 60 around the rotation axis X <b> 2 so that the abutting portion 642 of the sliding portion 64 contacts the cam surface 473. When in the contacted position, the switch pressing portion 80 contacts the switch pressing portion 83 to prevent the switch pressing portion 83 from moving in the direction in which the tact switch 90 is turned on.

  As shown in FIG. 9, the switch mechanism includes a cam pressing surface 80 having a cam portion 461 (461a to 461d) of the cam gear 40 and a contact portion 82a with the cam surface 461, and a tact attached to the printed circuit board P. The switch 90, the coil spring 71, and the switch pressing prevention portion 67 of the ice detecting shaft 60 are configured.

The switch pressing lever 80 includes a cylindrical portion 81, a cam sliding portion 82, a switch pressing portion 83, and a swing restricting portion 84. The cylindrical portion 81 has both ends in the axial direction at the first case portion 31. The switch pressing lever 80 is swingable about the rotation axis X3. The switch pressing lever 80 is rotatably supported by a support portion (not shown).

  The cam sliding portion 82 is a plate-like member extending toward the cam gear 40 side along the radial direction from the outer periphery of the cylindrical portion 81, and the cam surface of the cam gear 40 is disposed on the surface of the distal end portion on the switch pressing portion 83 side. An abutting portion 82 a that abuts on 461 is provided.

The switch pressing portion 83 is a plate-like member extending from the outer periphery of the cylindrical portion 81 in a direction orthogonal to the cam sliding portion 82, and the surface 83 a facing the tact switch 90 on the tip side is a press button of the tact switch 90. It is a pressing surface for pressing (not shown).
Furthermore, as shown to (a) of FIG. 7, the extension part 83b extended to the ice detection shaft 60 side is provided in the front end side of the switch press part 83. As shown in FIG.
In the extended portion 83b, when the angular position of the ice detecting shaft 60 around the rotation axis X2 is at a position where the contact portion 642 of the sliding portion 64 is in contact with the cam surface 473 (FIG. 8A). (See), the switch pressing block 67 of the ice detecting shaft 60 comes into contact.

As shown in FIG. 9, on the tip side of the switch pressing portion 83, a spring engagement portion 83 c is provided on the surface opposite to the tact switch 90.
A coil spring 71 whose one end is supported by a second case portion 32 (not shown) is engaged with the spring engaging portion 83c, and the switch pressing lever 80 is connected to the switch pressing portion 83 with a counterclockwise rotation around the rotation axis X3. A force in the direction of rotating in the rotating direction acts from the coil spring 71.

Therefore, as shown in FIG. 9, the switch pressing lever 80 presses the contact portion 82 a of the cam sliding portion 82 against the cam surface 461 (461 a to 461 d) of the cam gear 40 by the biasing force of the coil spring 71. It is designed to be maintained in a state.
Further, when the angular position of the cam gear 40 around the rotation axis X1 is at a position where the contact portion 82a is brought into contact with the cam surface 461b or the cam surface 461d, the rotation of the switch pressing lever 80 around the rotation axis X3 ( (Rotation in the counterclockwise direction) is further permitted, and the push button 90a (see FIG. 17) of the switch pressing portion 83 is pressed by the switch pressing portion 83, so that the tact switch 90 is turned on. .
Here, when the contact portion 82 a of the cam sliding portion 82 is in contact with the cam surfaces 461 a and 461 c of the cam gear 40, the switch button 90 a of the switch pressing portion 83 is not pressed by the switch pressing portion 83. It has become.

The swing restricting portion 84 is a plate-like member extending from the outer periphery of the cylindrical portion 81 to the side opposite to the cam sliding portion 82.
The swing restricting portion 84 is provided in a state where the distal end side is inserted into a guide groove (not shown) of the first case portion 31, and the swing range of the switch pressing lever 80 swinging around the rotation axis X3 is determined in advance. The predetermined range is set.

  The tact switch 90 is attached to the printed circuit board P, and is configured to output an ON signal to a control unit (not shown) when a push button (not shown) is pressed.

Hereinafter, the operation of the ice making device 1 will be described.
FIG. 10 is a flowchart showing the operation of the ice making device 1. FIG. 11 shows a cam surface 482 corresponding to the angular position around the rotation axis X1 of the scraping portion 232 and the angular position around the rotation axis X1 of the cam gear 40. It is a figure explaining the change of the contact position of 471-473 and the contact part 642 of the ice detecting shaft 60, and the contact position of the cam surface 461a-461d and the contact part 82a of the switch press lever 80, (A) is when the cam gear 40 is at the ice making position (origin position), (b) is when the cam gear 40 is at the ice detection position, and (c) is when the cam gear 40 is at the scraping operation position. It is the figure which showed each case.

  Driving of the ice making device 1 according to the embodiment is controlled by the ice making device 1 or a control unit (not shown) included in the refrigerator to which the ice making device 1 is attached.

  When the power of the ice making device 1 is turned on or an initialization signal is input, in step 1, the control unit executes an initialization operation for setting the ice detecting member 4 and the scraping member 23 at the ice making position.

In the initialization operation, first, the cam M is rotated by the motor M in the counterclockwise direction (in the direction of arrow A1 in FIG. 11A) as viewed from the first case portion 31 side.
Next, when the input of the ON signal from the tact switch 90 continues for a predetermined time, the rotation direction of the motor M is reversed and the cam gear 40 is rotated in the clockwise direction (in the direction of arrow A2 in FIG. 11A). ) To rotate.
When the ON signal is no longer input, the rotation of the motor M is stopped and the rotation of the cam gear 40 is stopped.

As a result, the cam gear 40 has an angle at which the contact portion 82a of the switch pressing lever 80 contacts the cam surface 461c and the contact portion 642 of the sliding portion 64 contacts the cam surface 482 in the vicinity of the communication port 47. It is placed at the position (ice making position). This state is shown in FIG.
In this ice making position, the scraping member 23 is disposed at an angular position where the scraping portion 232 is inclined toward the guide member 24, and the ice detecting member 4 flips the ice contact portion 4c with the base portion 4b facing in the horizontal direction. It is arranged at a position (position indicated by a virtual line in FIG. 6).

  The condition for reversing the rotation direction of the motor M is that the ON signal has been input for a predetermined period of time. The contact portion 82a of the switch pressing lever 80 is in contact with the cam surface 461d. This is for distinguishing the ON signal in the case from the ON signal in the case of being in contact with the cam surface 461b.

  In step 2, the control unit supplies water to the ice tray 21 and executes an ice making operation for solidifying the supplied water to form ice. Whether or not ice has been formed is determined based on whether or not a predetermined time set in advance has elapsed since the completion of water supply, the output of a thermostat (not shown) that monitors the temperature of the ice tray 21, and the like. Done.

After the ice is formed, the control unit starts a timer in Step 3 and checks whether or not a predetermined time has elapsed in Step 4.
When the predetermined time has elapsed, in step 5, the control unit performs ice detection by the ice detection member 4 by rotating the cam gear 40 to drive the ice detection member 4.

Specifically, the motor M rotates the cam gear 40 in the clockwise direction (in the direction of arrow A2 in FIG. 11A).
Then, the scraping portion 232 rotates around the rotation axis X1 in the direction indicated by the arrow A2 in the drawing, and the cam gear 40 rotates 11 degrees clockwise (arrow A2 direction) from the ice making position shown in FIG. At the time of rotation, it reaches an angular position where the abutting portion 642 of the sliding portion 64 abuts against the cam surface 471.
Here, since the coil spring 70 applies a biasing force that rotates the ice detecting shaft 60 in the clockwise direction in FIG. 9, when the cam gear 40 further rotates, the contact portion 642 faces the cam surface 473. The cam surface 471 is slid. At this time, the contact position between the contact portion 642 and the cam surface 471 moves clockwise around the rotation axis X2 in FIG. Then, in FIG. 6, the ice detecting shaft 60 rotates counterclockwise around the rotation axis X <b> 2, so the ice detecting member 4 directs the ice contact portion 4 c to the lower side of the ice tray 21. To move.

When the cam gear 40 reaches an angular position where the contact portion 642 of the sliding portion 64 contacts the cam surface 473, the angular position where the contact portion 82a of the switch pressing lever 80 contacts the cam surface 461d. (Ice detection position: 42 degrees from the origin position). This state is shown in FIG.
Therefore, at this time, the control unit determines whether or not ice having a predetermined height or more in the ice storage unit 1a is stored based on whether or not an ON signal is input from the tact switch 90.

When ice is not stored in the ice storage section 1a below the ice tray 21, the descending of the ice contact portion 4c of the ice detecting member 4 is not hindered by the ice, so that the ice detecting shaft 60 has the sliding portion 64. 9 is rotated in the clockwise direction around the rotation axis X2 until the angular position at which the abutting portion 642 abuts on the cam surface 473.
Then, the switch pressing prevention part 67 of the ice detecting shaft 60 contacts the switch pressing part 83 (extension part 83b) of the switch pressing lever 80 and prevents the tact switch 90 from being turned on by the switch pressing part 83. The signal is not input to the control unit.

On the other hand, when ice is stored in the ice storage portion 1a at a predetermined height or more, the ice detecting shaft 60 is rotated in the clockwise direction around the rotation axis X2 when the descending of the ice contact portion 4c is prevented by the ice. And the angular position at which the contact portion 642 of the sliding portion 64 contacts the cam surface 473 cannot be reached.
If it does so, since the switch press prevention part 67 of the ice detecting shaft 60 cannot contact | abut to the switch press part 83 (extension part 83b), it will be in the state in which ON of the tact switch 90 by the switch press part 83 is not prevented. Therefore, when the cam gear 40 reaches the angular position shown in FIG. 11B, the tact switch 90 is turned on by the switch pressing lever 80, and an on signal is input to the control unit.

Therefore, when the control unit receives an ON signal from the tact switch 90 while the cam gear 40 moves at an angular position where the sliding portion 64 of the ice detecting shaft 60 abuts against the cam surface 473 in step 6, It is determined that ice of a predetermined height or more is stored in the ice storage unit 1a, and if no ON signal is input, it is determined that ice is not stored.
In the embodiment, while the angular position around the rotation axis X1 of the cam gear 40 is within the range of 30 to 55 degrees in the clockwise direction from the ice making position shown in FIG. The sliding portion 64 slides on the cam surface 473, and the control means makes a determination based on the presence or absence of an ON signal within this angular range.

If it is determined in step 6 that ice of a predetermined height or more is not stored in the ice storage unit 1a, in step 7, the control unit continues the rotation of the cam gear 40 to move the ice detecting member in FIG. Return to the ice making position (initial position) indicated by the phantom line. This is because, in preparation for scraping out the ice in Step 8, the ice detecting member is disposed at an initial position where there is no possibility of coming into contact with the ice falling from the ice tray.
Specifically, the cam gear 40 continues to rotate in the clockwise direction (in the direction of arrow A2 in FIG. 11B), and the angle at which the contact portion 642 reaches the position indicated by the phantom line in FIG. 11B. The cam gear 40 is rotated to the position.

Then, when the rotation angle from the origin position of the cam gear 40 (see FIG. 11A) exceeds 55 degrees, the contact portion 642 slides on the cam surface 472 in a direction away from the cam surface 473. become.
At this time, the contact position between the contact portion 642 and the cam surface 472 moves counterclockwise around the rotation axis X2 in FIG. Then, in FIG. 6, since the ice detecting shaft 60 rotates clockwise around the rotation axis X2, the ice detecting member 4 moves the ice contact portion 4c above the ice tray 21 (ice storage portion 1a). (In the direction of separating from).

Then, when the rotation angle of the cam gear 40 from the ice making position (see FIG. 11A) reaches 79 degrees, the contact portion 642 reaches the position indicated by the phantom line in FIG. , Abuts against the cam surface 482.
As a result, the ice detecting member 4 returns to the ice making position indicated by the phantom line in FIG.

  Subsequently, in step 8, the control unit executes an ice scraping operation in the ice tray 21 by the scraping member 23.

Specifically, first, the rotation of the motor M is stopped, and the rotation of the cam gear 40 is stopped. Then, the ice tray 21 is heated by the heater 25 to melt the contact interface with the ice tray 21, thereby separating the ice from the ice tray 21.
Here, whether or not the ice has separated from the ice tray 21 is determined by determining whether or not a predetermined time has elapsed from the start of heating by the heater 25, the output of a thermostat (not shown) that monitors the temperature of the ice tray 21, Etc.

Subsequently, the motor M rotates the cam gear 40 in the clockwise direction (the direction indicated by the arrow A2 in FIG. 11B) again.
Then, the contact portion 642 slides on the cam surface 482, and the scraping portion 232 rotates around the rotation axis X1 in the direction indicated by the arrow A2 in the drawing.
As shown in FIG. 11C, when the cam gear 40 continues to rotate in the direction indicated by the arrow A2, the ice in the ice tray 21 is pushed by the scraping portion 232 that rotates in the direction indicated by the arrow A2. However, it rotates around the rotation axis X <b> 1 along the inner peripheral surface of the ice tray 21 and is finally pushed up to the upper surface of the guide member 24.
And the pushed-up ice falls to the ice storage part 1a from the side surface opposite to the side surface on which the ice detecting member 4 is provided.

In step 9, the control means executes a return operation for returning the ice detecting member 4 and the scraping member 23 to the ice making position.
Specifically, first, when a predetermined time has elapsed from the input of the ON signal, the rotation direction of the motor M is reversed.
When the input of the ON signal from the tact switch 90 continues for a predetermined time, the motor M is reversed in the clockwise direction (CW direction), and the cam gear 40 is rotated in the clockwise direction. When the ON signal is no longer input, the rotation of the motor M is stopped and the rotation of the cam gear 40 is stopped.
As a result, the cam gear 40 returns to the ice making position shown in FIG.

When it is determined in step 6 that ice of a predetermined height or more is stored in the ice storage unit 1a, in step 10, the control unit reverses the rotation of the cam gear 40 and moves the ice detecting member. , The ice making position (initial position) indicated by the phantom line in FIG. 6 is returned.
Specifically, the rotation direction of the motor M is reversed, and the cam gear 40 is rotated clockwise (in the direction of arrow A1 in FIG. 11B).
Then, after the ON signal is no longer input, when the ON signal is input for a predetermined time, the rotation direction of the motor M is reversed and the cam gear 40 is rotated in the clockwise direction ((a) in FIG. 11). In the direction of arrow A2).
When the ON signal is no longer input, the rotation of the motor M is stopped and the rotation of the cam gear 40 is stopped.

As a result, the cam gear 40 has an angle at which the contact portion 82a of the switch pressing lever 80 contacts the cam surface 461c and the contact portion 642 of the sliding portion 64 contacts the cam surface 482 in the vicinity of the communication port 47. It is placed at the position (ice making position). This state is shown in FIG.
In this ice making position, the scraping member 23 is disposed at an angular position where the scraping portion 232 is inclined toward the guide member 24, and the ice detecting member 4 flips the ice contact portion 4c with the base portion 4b facing in the horizontal direction. It is arranged at a position (position indicated by a virtual line in FIG. 6).
As described above, in step 10, the ice detecting member 4 is returned to the ice making position when the ice contact portion 4c of the ice detecting member 4 is held in the ice storage portion 1a while being lowered, for example, from the refrigerator to the ice storage. This is because the ice detecting member 4 may collide with the ice or the ice storage when the ice is removed.
After the cam gear 40 and the scraping portion 232 are returned to the ice making position shown in FIG. 11A by the process of step 10, the process proceeds to step S3.
Thereafter, the processes of Step 3 to Step 6 and Step 10 are repeated until it is determined that ice of a predetermined height or more is not stored in the ice storage unit 1a.

  Here, the scraping member 23, the guide member 24, the heater 25, the cam gear 40, and the motor M in the embodiment constitute the deicing means in the invention.

As described above, in the embodiment, ice removing means for taking out ice from the ice tray 21 and dropping it from the side of the ice tray 21 on the side where the guide member 24 is provided, and an ice storage section for storing the dropped ice. In an ice making device 1 comprising 1a and an ice detecting member 4 that moves up and down in the ice storage portion 1a at the time of ice detection for inspecting the amount (height) of ice in the ice storage portion 1a, the ice detecting member 4 is connected to an ice tray. It was set as the structure provided in the side opposite to the side where 21 ice falls.
With this configuration, since the ice does not fall on the side where the ice detecting member 4 is provided, it is possible to prevent the falling ice and the ice detecting member 4 from coming into contact with each other and preventing the ice detecting member 4 from being damaged. Is not obstructed by the ice detecting member 4.

Furthermore, the ice detecting member 4 is configured to move up and down by moving in the vertical direction with respect to the ice tray 21.
If comprised in this way, since the ice detection member 4 does not move so that it may wrap around the side of the ice tray 21, it is not necessary to provide the space for ensuring the movement of the ice detection member 4 in the width direction of the ice making apparatus 1. The size in the width direction can be suppressed.

The ice making device 1 is provided in the ice making chamber with a gap between the ice making tray 21 to which the heater 25 is attached and the fixing member 300 that is the wall of the ice making chamber. It was set as the structure arrange | positioned.
If comprised in this way, since the ice-detecting member 4 can be provided using the clearance gap ensured when providing the ice-making tray 21 with which the heater 25 was attached in an ice-making chamber, the magnitude | size of the width direction of the ice making apparatus 1 can be provided. This can be suppressed.

  In the embodiment, the connecting portion 4a of the ice detecting member 4 is rotatable about the rotation axis X2 extending in the width direction of the ice tray 21, and the base portion 4b and the ice contact portion extending in the radial direction from the connecting portion 4a. 4c is pivoted around the rotation axis X2 on the side of the long side surface of the ice tray 21 so that the ice contact portion 4c moves up and down (vertical direction) with respect to the ice tray 21. However, the ice contact portion 4c is constituted by a member that linearly moves in the radial direction of the rotation axis X2, and the height of ice in the ice storage chamber 1a is detected by the linearly moving member. good.

FIG. 12 is a diagram illustrating a modified example of the ice detecting member.
The ice detecting member 100 according to the modified example is connected to a connecting portion 62 (not shown) of the ice detecting shaft 60 from the axial direction and extends in the radial direction of the ice detecting shaft 60, and from the base 101 to the ice making tray. 21 and an ice contact portion 102 extending to the lower side of 21.
The ice contact portion 102 has a shape (U shape in plan view) that matches the heater 25 (see FIG. 4) in plan view, and when the ice detecting member 100 is placed at the ice making position, ice making is performed. The lower surface of the heater 25 exposed at the bottom of the dish 21 is covered with the ice contact portion 102 over the entire surface.

In the ice making device 1 employing the ice detecting member 4 described above, the distribution of the ice height in the ice storage section 1a is uneven. For example, in FIG. 5, the ice height on the fixing member 300 side is low, and the other side (guide) When the height of the ice on the member 24 side is high, it is detected that the ice is insufficient, and even if the ice is sufficiently stored in the ice storage unit 1a, the ice is newly supplied.
In the ice making device 1A according to the modification, the ice detecting member 100 includes the ice contact portion 102 that extends to the lower side of the ice tray 21. Therefore, the contact area with the ice in the ice storage portion 1a is the ice detecting member 4. It becomes wider than the case.
Then, even if the ice height distribution in the ice storage unit 1a is uneven, it can be determined whether or not the ice stored is insufficient based on the position of the most ice in the ice storage unit 1a. Even though the ice is sufficiently stored in the part 1a, it is determined that the ice is insufficient due to the uneven distribution of the ice, and the ice is newly supplied to the ice storage part 1a. This can be suitably prevented.

Further, when the ice detecting member 100 moves in the upward direction away from the ice storage unit 1a and reaches the ice making position indicated by the phantom line in FIG. 6, the lower surface of the heater 25 exposed at the bottom of the ice making tray 21 is entirely covered. Since the structure is covered by the ice contact portion 102, the radiant heat of the heater 25 can be prevented from directly reaching the ice stored in the ice storage portion 1a.
Therefore, the temperature of the ice storage unit 1a and the ice making chamber can be prevented from rapidly rising due to the radiant heat of the heater 25, and energy loss in the ice making device and the refrigerator equipped with the ice making device can be suppressed.

DESCRIPTION OF SYMBOLS 1, 1A Ice making apparatus 1a Ice storage part 2 Ice making unit 3 Drive unit 4, 100 Ice detection member 4c, 102 Ice contact part 21 Ice tray 22 Water supply part 23 Scraping member 24 Guide member 25 Heater 31 1st case part 32 2nd case Part 40 cam gear 48 arc wall 50 reduction gear train 60 ice detecting shaft 64 sliding part 641 projecting part 642 abutting part 642a abutting surface 642b abutting surface 65 spring engaging part 67 switch pressing prevention part 70, 71 coil spring 80 switch Press lever 82 Cam sliding part 82a Contact part 83 Switch pressing part 90 Tact switch 300 Fixing member 461 Outer wall 461a-461d Peripheral wall part (cam surface)
471-473 edge (cam surface)
482 Inner circumference (cam surface)
Ic Ice M Motor P Printed circuit board

Claims (5)

Ice removing means for dropping the ice in the ice tray from the side of the ice tray;
An ice storage unit for storing the dropped ice;
In an ice making device comprising: an ice detecting member that moves up and down in the ice storage part at the time of ice detection for inspecting the amount of ice in the ice storage part,
2. The ice making apparatus according to claim 1, wherein the ice detecting member is provided on a side opposite to a side where the ice of the ice making tray falls.   The ice making apparatus according to claim 1, wherein the ice detecting member is moved up and down by movement in a vertical direction with respect to the ice making tray. The deicing means includes a heater for heating the ice tray,
The ice making device is provided in the ice making chamber with a gap between the ice making tray to which the heater is attached and the wall portion of the ice making chamber,
The ice making device according to claim 1 or 2, wherein the ice detecting member is disposed in the gap.   The ice making device according to any one of claims 1 to 3, wherein the ice detecting member includes an ice contact portion that extends to a lower side of the ice tray. The heater is attached to the lower surface of the ice tray,
The ice contact portion is formed in a shape that covers the heater from a lower side of the ice tray when the ice detecting member moves in a rising direction away from the ice storage portion. 4. The ice making device according to 4.

Images