JP3909190B2 - Automatic ice machine drive - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a drive device for an automatic ice maker that is installed in a refrigerator and supplies ice when it is manufactured and when the lack of ice in an ice storage container is detected.
[0002]
[Prior art]
In recent years, household refrigerators and the like having an automatic ice making function are known, and examples of a drive device for an automatic ice making machine attached to the refrigerator include, for example, devices described in JP-A-8-313132, etc. Various proposals have been made.
[0003]
Such a drive device is provided with detection means for inspecting the amount of ice in the ice storage container or detecting the rotation angle of the ice tray by controlling the drive of the motor. The detection means is configured such that a switch is fixed on a circuit board attached at a predetermined position in the storage case, and this switch is turned on / off by the action of a drive coupling mechanism that receives the driving force of the motor. .
[0004]
[Problems to be solved by the invention]
Due to the characteristics of the ice making machine as described above, the switch has an accurate position in the storage case in order to accurately recognize the rotation angle of the ice tray and the detection result of the amount of ice by the ice detecting lever. Need to be attached to. However, in the above-described apparatus, the switch is mounted on the circuit board, and the circuit board is mounted on the bottom surface of the storage case. For this reason, there exists a problem that the positional accuracy of the height direction of a switch worsens because the dimensional error of these each member accumulates.
[0005]
In addition, the circuit board interposed between the switch and the storage case is shrunk due to heat during the soldering operation or is naturally warped. In addition, the circuit board usually has a configuration in which the terminal of the switch is projected through the board on the side opposite to the mounting surface of the switch (configuration in which the terminal of the switch protrudes from the back surface of the board). It is attached to the bottom of the case in a state where a space to be projected is secured between the storage case and the case. For this reason, when the switch is pressed, the circuit board is slightly bent to the above-described space side under the pressing force. As described above, since the switch is mounted in the storage case via the circuit board that is likely to be distorted in dimensional accuracy and is bent by pressing, the positional accuracy of the switch may be further deteriorated. Furthermore, since the switch is configured to operate by receiving the pressure of the pressing member, the switch is subjected to stress over time by continuing to receive the pressure, and the positional deviation can gradually increase due to this stress. It has sex.
[0006]
In view of the above-described problems, the present invention provides a drive device for an automatic ice maker that has a higher positional accuracy of the push switch in the storage case and that has a more reliable and precise detection operation. Objective.
[0007]
[Means for Solving the Problems]
In order to achieve such an object, in the present invention, when the lack of ice in the ice storage container is detected, the ice tray is inverted to drop the ice into the ice storage container, and then the ice tray is returned to its original position to return the ice. In the drive device of the automatic ice maker that manufactures, there is a press switch that is pressed / non-pressed corresponding to the rotational drive of the ice tray, and the press switch has a contact surface with a pressing member that presses the press switch, The surface on the opposite side is brought into direct contact with the end face of the convex portion formed inside the storage case, so that this is used as a reference position in the height direction, and is arranged in the storage case based on this reference position.
[0008]
For this reason, the pressure switch for detecting the amount of stored ice and detecting the rotation angle of the ice tray is attached to the storage case with high accuracy. In addition, since the pressing force applied from the pressing member to the pressing switch is received by the convex portion in the storage case, it is possible to prevent the positional displacement of the pressing switch with time and to improve the mounting strength. As a result, if a member related to the on / off operation of the push switch is accurately incorporated in the storage case, the ice storage amount detection, the rotation angle of the ice tray, and the on / off timing of the push switch are accurately linked.
[0009]
In another aspect of the invention, in addition to the above-described automatic ice maker driving device, the pressing member is rotatably supported by a support portion provided in the storage case. For this reason, both the reference surface (convex part) for attaching the above-described press switch and the support part for supporting the press member are integrally formed as a part of the storage case. As a result, the pressing member that turns on and off the pressing switch is also positioned directly with reference to the storage case as in the case of the pressing switch, and accumulation of mounting tolerances and component accuracy tolerances occurs between the pressing member and the pressing switch. Therefore, the pressing member is arranged with higher accuracy with respect to the pressing switch.
[0010]
According to another invention, in addition to the above-mentioned automatic ice maker driving device, the pressing member is always urged in the direction of pressing the pressing switch, and the storage case is lowered into the ice storage container. An ice detecting shaft that rotates integrally with an ice detecting member that performs ice detection in the ice storage container, and this ice detecting shaft is rotatably supported by a support member formed in the storage case, A blocking piece is provided that operates the pressing member against an urging force when the ice detecting shaft rotates by a predetermined angle or more and prevents the pressing operation of the pressing switch of the pressing member.
[0011]
Therefore, the reference surface (convex part) for attaching the above-described press switch and the support member that supports the ice detecting shaft are both integrally formed as a part of the storage case. As a result, the ice detecting shaft provided with the blocking piece that directly acts on the pressing member that switches the pressing switch on and off is also positioned directly with reference to the storage case, like the pressing switch. Accumulation of mounting tolerances and component accuracy tolerances does not occur between the press switches, and the ice detecting shaft is arranged with higher accuracy with respect to the press switch.
[0012]
In another invention, in addition to the above-mentioned automatic ice maker driving device, the circuit board is fixed to the end surface of the motor serving as the driving source of the ice tray, and the pressing switch is configured so that the pressing direction is parallel to the circuit board surface. After the motor is placed at a predetermined position in the storage case, the pressing switch is brought into contact with the end surface of the convex portion by rotating the circuit board with the fixing portion to the motor as a base point. In this way, the circuit board is arranged in the storage case. For this reason, the pressure switch is moved to a predetermined position in the storage case by placing the motor at a predetermined position in the storage case and rotating the circuit board until the press switch contacts the convex portion in the storage case. Arranged with high accuracy.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0014]
FIG. 1 shows a drive device for an automatic ice maker and an ice maker driven by the drive device according to an embodiment of the present invention. The automatic ice making machine 1 automatically performs ice making, deicing, etc., is installed in an ice making chamber of a refrigerator, and operates by a driving method described later.
[0015]
The automatic ice maker 1 includes an ice tray 2 disposed above an ice storage container (not shown), an ice detection lever 3 as an ice detecting member that moves up and down to detect the amount of ice stored in the ice storage container, and an ice tray 2. A liquid supply means (not shown) for supplying liquid such as water and a driving device 5 that drives the ice tray 2 and the ice detecting lever 3 in conjunction with each other are provided.
[0016]
The drive device 5 lowers the tip of the ice detecting lever 3 into the ice storage container, and detects the presence or absence of ice in the ice storage container based on the descending distance. And when this drive device 5 detects the shortage of ice, it reverses the ice-making tray 2 to the ice-off position and drops the ice into the ice storage container. In other words, the inverted ice tray 2 is twisted and deformed when the protruding portion 2a on the other end hits a contact piece (not shown) provided on the machine frame 6 of the refrigerator or the automatic ice making machine 1, and this deformation is used. Drop the ice. Thereafter, the drive device 5 returns the ice tray 2 to the ice making position. Then, liquid is supplied to the ice tray 2 at this ice making position, and ice is manufactured.
[0017]
As shown in FIGS. 2 and 3, the drive device 5 is connected to the ice tray 2 via a drive wheel train 15 and reverses the cam wheel 10, and the cam wheel 10 is operated to operate the ice detecting lever 3. The ice detecting shaft 31 to be operated, the motor 13 serving as a driving source for the cam wheel 10 and the ice detecting shaft 31, and the pressing switch 42 and the pressing switch 42 for detecting the detection result of the ice amount by the ice detecting lever 3 are pressed. / A pressing member 41 for non-pressing. The internal mechanism of the driving device 5 is disposed at a predetermined position in the storage case 9 composed of two case halves 9a and 9b. Inside the storage case 9, the motor 13 and the push switch 42 are provided. A circuit board 51 to which each terminal is connected is accommodated.
[0018]
In addition, as shown in FIG. 4, the driving device 5 of the present embodiment has a contact surface with the pressing member 41 of the pressing switch 42 on the convex portion 9 h erected on the bottom of the case half 9 b of the storage case 9. The surface on the opposite side is in direct contact. The pressing switch 42 is pressed to the back side in FIG. 2 by the pressing member 41. On the back side of the pressing switch 42, a convex portion 9h that supports the pressing switch 42 is erected from the bottom surface of the case half 9b. Has been.
[0019]
That is, the pressing switch 42 is mounted on the circuit board 51 so that the substrate surface of the circuit board 51 and the pressing direction of the pressing member 41 that presses the pressing switch 42 are parallel, and the rear end surface portion is a convex portion. It arrange | positions so that it may contact with the upper end surface of 9h directly. The lower end portion of the circuit board 51 faces the bottom surface of the storage case 9 with a slight clearance. As described above, the push switch 42 is brought into contact with the convex portion 9h of the storage case 9 without using the circuit board 51, so that mounting tolerances and component tolerances between the press switch 42 and the storage case 9 are accumulated. The pressing switch 42 is accurately arranged with respect to the storage case 9.
[0020]
The driving device 5 of the present embodiment also positions the pressing member 41 for pressing / non-pressing the pressing switch 42 and the positioning of the ice detecting shaft 31 for operating the pressing member 41 in the storage case 9. Part (the configuration will be described later). In addition, the cam wheel 10 is disposed in the storage case 9 with the base portion 7 formed on the bottom surface of the storage case 9 as a rotation center.
[0021]
In this way, the pressing switch 42, the pressing member 41, the cam wheel 10 and the ice detecting shaft 31 are positioned by the positioning portions formed on the storage case 9, respectively. In addition, in the present embodiment, the switch pressing operation preventing piece 31d of the ice detecting shaft 31 is in direct contact with the surface of the pressing member 41 on the side where the pressing switch 42 is pressed. For this reason, component tolerances and assembly tolerances between the members do not accumulate, positional accuracy of the pressing switch 42 with respect to the pressing member 41, positional accuracy between the ice detecting shaft 31 and the cam wheel 10, and ice detecting shaft 31. Thus, the positional accuracy of the pressing member 41 becomes good, and the rotation angle of the cam wheel 10 and the ice detecting shaft 31 and the ON / OFF of the pressing switch 42 become more precise.
[0022]
The cam wheel 10 is rotated by a motor 13 serving as a drive source. FIG. 5 shows the surface of the cam wheel 10 on which the cam surface is formed. That is, FIG. 5 is a view of the cam wheel 10 viewed from the direction indicated by the arrow V in FIG.
[0023]
An output shaft 25 is integrally formed with the cam wheel 10. The output shaft 25 protrudes outward from the drive device 5 through a hole provided in one case half 9 a and is connected to the ice tray 2. Therefore, the cam wheel 10 and the ice tray 2 rotate together.
[0024]
The end of the output shaft 25 that is not connected to the ice tray 2 has a cylindrical shape and is rotatably supported by a circular base 7 provided in the case half 9b. Further, a cylindrical friction member 8 is loosely disposed in a friction state on the outer peripheral surface of the end portion of the output shaft 25.
[0025]
Further, an ice detecting shaft is provided on the outer peripheral surface of the cylindrical friction member 8 at the ice detecting position when driven in the ice making position direction (the rotation direction opposite to the deicing position direction where the ice is dropped from the ice tray 2). A rotation blocking piece 8b for blocking the rotation of 31 is provided. When the friction member 8 rotates together with the cam wheel 10 in the ice making position direction, the rotation blocking piece 8b moves to a position where it engages with the engaging piece 31b of the ice detecting shaft 31, and engages with the engaging piece 31b. .
[0026]
Therefore, when the ice detecting shaft 31 is driven in the ice making position direction, the engaging convex portion 31a faces the ice shortage detecting position portion 28c (see FIG. 5) of the cam surface 28 for the ice detecting shaft of the cam wheel 10. However, since the rotation is blocked by the above-described rotation blocking piece 8b, it does not rotate according to the cam surface shape. As described above, since the ice detecting shaft 31 does not rotate even when it reaches the ice detecting position, the switch pressing operation blocking piece 31d formed on the ice detecting shaft 31 causes the pressing member 41 that presses the pressing switch 42 to be described later. The rotation cannot be prevented and the push switch 42 is turned on.
[0027]
That is, in the rotation of the ice tray 2 after the ice removing operation, the pressing member 41 is swung by the urging force of the coil spring 44 at the ice detecting position, and the pressing switch 42 is irrespective of the amount of ice in the ice storage container. Always on. With this configuration, the control for driving the ice tray 2 can be facilitated.
[0028]
On the other hand, when the friction member 8 rotates together with the cam wheel 10 in the direction of the deicing position, the rotation prevention piece 8b moves to a position outside the rotation range of the engagement piece 31b of the ice detecting shaft 31, and the engagement piece It does not engage with 31b. For this reason, the ice detecting shaft 31 can freely rotate at the ice detecting position according to the concave shape of the ice detecting shaft cam surface 28 described later.
[0029]
On the other hand, as shown in FIGS. 3 and 5, an annular recess 27 is formed on the side surface 10 c of the cam wheel 10 that faces the case half 9 b. In the recess 27, an ice detecting shaft cam surface 28 having an inner wall as a cam surface is provided, and a pressing member operating cam surface 29 having an inner wall as a cam surface is also formed on the outer side thereof. . Each of the cam surfaces 28 and 29 is formed on the inner peripheral surface portion of the side wall of the extending portion that extends substantially parallel to the axis that is the rotation center of the cam wheel 10.
[0030]
As shown in FIG. 5, the ice detecting shaft cam surface 28 has an ice detecting non-operating position portion 28a and an ice shortage detecting position portion 28c. The ice detection non-operation position portion 28a is a section in which the ice detection lever 3 is maintained without being lowered. Further, the ice shortage detection position portion 28c is a section in which the ice detecting lever 3 is maintained in the lowest lowered state when ice is insufficient. The ice shortage detection position portion 28c has a concave shape. The ice detecting shaft 31 tends to rotate by the urging force of the coil spring 32 every time the engaging convex portion 31a is fitted into the ice shortage detecting position portion 28c.
[0031]
Further, as shown in FIG. 5, the pressing member operating cam surface 29 includes a first signal generating cam portion 29a for outputting a signal at the ice making position and a second signal for outputting a signal at the ice detecting position. Signal generating cam portion 29b and a third signal generating cam portion 29c for outputting a signal at the deicing position. Each of these signal generating cam portions 29a, 29b, and 29c is recessed. The pressing member 41 tends to swing toward the pressing switch 42 by the urging force of the coil spring 44 every time the cam contact portion 41a is fitted in these recesses.
[0032]
When the ice detecting shaft 31 is rotated by a predetermined angle (here, 30 degrees) or more, the switch pressing operation preventing piece 31d formed on the ice detecting shaft 31 rotates the pressing member 41 that presses the pressing switch 42 as described later. The movement is stopped.
[0033]
With this configuration, when the rotation angle of the cam wheel 10 is in the ice making position and the ice removing position, that is, in a state where the ice tray 2 is horizontally stationary for ice making and in a state where the ice is twisted off by being inverted. 42 is turned on. Further, the push switch 42 outputs an ice detection signal when the ice is full due to the ice detection operation and when the ice is passing through the ice making position when driven in the direction of the ice making position after deicing. Thus, in the present embodiment, the push switch 42 outputs a signal for notifying the ice detection result and also outputs a signal for detecting the position of the ice tray 2.
[0034]
With this configuration, when the ice in the ice storage container is insufficient when rotating in the direction of the deicing position, the ice detecting shaft 31 rotates 30 degrees or more so that the push switch 42 is not turned on (pressed). It is configured. On the other hand, when the ice storage container is in a state where a predetermined amount or more of ice is stored, if the ice detecting lever 3 hits the ice in the ice storage container and the ice detecting shaft 31 cannot rotate more than a predetermined angle, the ice detecting shaft The engaging piece 31b of 31 cannot prevent the pressing member 41 from rotating. Therefore, in this case, the pressing member 41 swings at the ice detection position by the urging force of the coil spring 44, and the pressing switch 42 is pressed by the swing.
[0035]
In this embodiment, such a configuration is used, but conversely, it is configured so that it is always turned off when driven in the direction of the ice making position, and when the ice is full when driven in the direction of the ice detecting position. It is good also as a structure which turns on.
[0036]
The ice detecting shaft 31 is operated by the cam wheel 10 and can be rotated up to 35 degrees. As shown in FIG. 6, the ice detecting shaft 31 includes an engaging projection 31a, an engaging piece 31b, a spring engaging portion 31c, a switch pressing operation preventing piece 31d, and a thrust drop prevention formed over the entire circumference. A jetty 31e, a lever connecting portion 31f, a case receiving portion 31g, and a guide piece 31h are provided.
[0037]
A case receiving portion 31g constituted by a convex portion at one end of the ice detecting shaft 31 is rotatably supported by a receiving hole (not shown) formed in the case half 9b. On the other hand, the lever connecting portion 31f formed at the other end of the ice detecting shaft 31 protrudes outside the storage case 9, and the fulcrum portion of the ice detecting lever 3 is fitted into the lever connecting portion 31f. It is. Actually, the ice detecting lever 3 is rotated into the ice storage container to detect the amount of ice in the ice storage container. The ice detecting shaft 31 is inserted first into the receiving hole of the case receiving portion 31g, the coil spring 32 is engaged with the spring engaging portion 31c, and the engaging convex portion 31a is pressed against the cam surface 28 for the ice detecting shaft of the cam wheel 10. In this state, by placing the lever connecting portion 31 f side in the storage case 9, the lever connection portion 31 f is positioned in the storage case 9 so as to be rotatable.
[0038]
As described above, the ice detecting shaft 31 is positioned by the positioning portion formed in the storage case 9. That is, the case receiving portion 31g is positioned in a receiving hole formed in a member erected on the bottom surface of the storage case 9, and the neck portion A (see FIG. 6) is positioned by a receiving hole formed in the case side surface. The ice shaft 31 is positioned in the storage case 9 as a whole. That is, as with the push switch 42, it is positioned at a part of the storage case 9. For this reason, component tolerances and mounting tolerances do not accumulate between the ice detection shaft 31 and the storage case 9, and the ice detection shaft 31 is accurately placed in the storage case 9. As a result, a dimensional tolerance with respect to the press switch 42 mounted in the storage case 9 with high accuracy is not accumulated, and a positional relationship with good positional accuracy can be obtained.
[0039]
Further, the engaging convex portion 31 a formed in the vicinity of the case receiving portion 31 g of the ice detecting shaft 31 has a shape that protrudes radially outward from the outer peripheral surface of the ice detecting shaft 31 and is curved from the middle position. The engaging convex portion 31 a is a cam follower that contacts the ice detecting shaft cam surface 28 formed in the cam wheel 10.
[0040]
Similarly, the engagement piece 31b provided in the vicinity of the end of the ice detecting shaft 31 can be brought into contact with the rotation prevention piece 8b of the friction member 8 that is coaxially fitted with the output shaft 25 in a friction state. Has been.
[0041]
Further, the guide piece 31h enters a guide groove (not shown) formed in the back side portion of the top plate of the case half 9a, and moves along the guide groove. The guide piece 31h regulates the rotation range of the ice detecting shaft 31.
[0042]
As shown in FIG. 3, the pressing member 41 is rotatable in each U-shaped groove 53a provided at the upper edge portion of the two end plates 53 erected on the bottom surface of one case half 9b. It is supported. That is, each U-shaped groove 53a provided in the storage case 9 serves as a support portion that rotatably supports the pressing member. As shown in FIG. 7, the pressing member 41 has a “G” shape when viewed from the side.
[0043]
In addition, a protruding arm 41 b serving as a pressed portion urged by the coil spring 44 is formed at a predetermined position of the pressing member 41. The protruding arm 41 b is located in the vicinity of the switch pressing operation blocking piece 31 d provided on the ice detecting shaft 31. In a state where the switch pressing operation blocking piece 31d is in contact with the protruding arm 41b, the pressing member 41 cannot swing.
[0044]
On the other hand, a button 42a of the push switch 42 is disposed at a position facing the protruding arm 41b. A protrusion 41 c having a mountain shape is provided on the surface of the pressing arm 41 on the side not facing the pressing switch 42 of the protruding arm 41 b and enters into one end of the coil spring 44. As shown in FIG. 3, the other end of the coil spring 44 is placed in an engagement cylinder 21c provided in the case half 9a, and a shaft (not shown) in the engagement cylinder 21c is placed in the end. It has entered.
[0045]
Further, the central portion of the pressing member 41 is a rotation support portion 41d that supports swinging. Both ends of the rotation support portion 41d enter the U-shaped grooves 53a, and the rotation support portion 41d is connected to the rotation support portion 41d. Swings as the center. Further, the pressing member 41 is provided with a swing restricting portion 41e, and even if the cam contact portion 41a receives a circumferential force from the cam wheel 10, the end surface of the swing restricting portion 41e is the end plate 53. Regulated by the inner wall. Therefore, the pressing member 41 does not incline because one side of the rotation support portion 41d is lifted from the bottom of the U-shaped groove 53a, and moves accurately along the pressing member operation cam surface 29 without shifting the center of oscillation. It is supposed to be.
[0046]
In this way, the pressing member 41 is rotatably supported in a positioning portion formed in the storage case 9, specifically, in each U-shaped groove 53 a provided in the upper edge portion of the both end plates 53. That is, as with the push switch 42, it is positioned at a part of the storage case 9. For this reason, component tolerances and mounting tolerances do not accumulate between the pressing member 41 and the storage case 9, and the pressing member 41 is accurately placed in the storage case 9. As a result, a dimensional tolerance with respect to the press switch 42 mounted in the storage case 9 with high accuracy is not accumulated, and a positional relationship with good positional accuracy can be obtained.
[0047]
The pressing switch 42 is disposed between the motor 13 and the ice detecting shaft 31 as shown in FIG. The motor terminal 13b located on the rear end face of the motor 13 and the terminal 42b protruding to the side of the pressing switch 42 are connected to a circuit board 51 arranged so as to be parallel to the side wall.
[0048]
A bearing bush 13c for bearing the output shaft of the motor 13 is fitted in the hole 51a formed in the circuit board 51, and the end face of the motor 13 is configured so that the circuit board 51 can be rotated around the hole 51a. It is fixed to. When the motor 13 and the pressure switch 42 connected via the circuit board 51 are arranged in the storage case 9, the motor 13 is first placed on a motor placement portion (not shown). At this time, the lower end surface of the circuit board 51 faces the bottom surface of the storage case 9 with a slight clearance as described above.
[0049]
Then, with the motor 13 fixed in the storage case 9, the circuit board 51 is slightly rotated around the hole 51 a in the direction of narrowing the clearance, and the rear end surface of the push switch 42 is placed in the storage case 9. Is brought into contact with the upper end surface of the convex portion 9h. Thereby, the motor 13, the circuit board 51, and the pressing switch 42 are positioned. That is, the contact between the pressing switch 42 and the convex portion 9h becomes the reference position in the height direction of the pressing switch 42 as described above, and is also used for positioning the circuit board 51.
[0050]
After the circuit board 51 to which the pressing switch 42 and the motor 13 are thus connected is arranged in the case half 9b of the storage case 9, the case half 9a is placed over the case half 9b. As shown in FIG. 4, the case half 9a is formed with a holding portion 9k having a boss 9j that is slightly crushed by the upper edge portion of the circuit board 51. With this configuration, the circuit board 51 receives a little force from the case half 9a side of the storage case 9, and the pressing switch 42 is received by the case half 9b (bottom side). The pressing switch 42 and the circuit board 51 are clamped with high positional accuracy.
[0051]
The above-described embodiment is a preferred embodiment of the present invention, but is not limited to this, and various modifications can be made without departing from the scope of the present invention.
[0052]
【The invention's effect】
As described above, the automatic ice maker drive device of the present invention is in a state in which the surface opposite to the contact surface with the pressing member of the pressing switch is in direct contact with the end surface of the convex portion formed inside the storage case. Is a reference position, and the push switch is disposed in the storage case. For this reason, mounting tolerances and component tolerances do not accumulate when the push switch is attached, and the push switch can be attached to the storage case with high accuracy. Further, a positioning part of the ice detecting shaft provided with a pressing member for operating the pressing switch and a blocking piece for blocking the pressing operation of the pressing member is provided in the storage case on which the reference surface of the pressing switch is formed. As a result, the component tolerances of the switch mechanism for operating the push switch do not accumulate, and the push switch is accurately linked to the ice storage detection and the ice tray turning angle. As a result, the reliability of the detection operation of the drive device can be improved.
[Brief description of the drawings]
FIG. 1 is a side view of an automatic ice making machine according to an embodiment of the present invention.
FIG. 2 is a front view showing the driving apparatus of the automatic ice maker shown in FIG. 1, wherein one case half is removed and the inside can be observed;
3 is a cross-sectional development view showing a connection relationship of drive wheel trains of the drive device of FIG. 2;
4 is a cross-sectional view taken along arrow IV-IV in FIG. 2;
5 is a bottom view of the cam wheel of the drive device of FIG. 3 as seen from the direction of arrow V. FIG.
6 is a front view showing an ice detecting shaft of the drive device of FIG. 2; FIG.
7 is a bottom view of the pressing member of the drive device of FIG. 2 as viewed from the direction of arrow VII.
[Explanation of symbols]
1 Automatic ice making machine 2 Ice making tray 3 Ice detection lever (material for ice detection)
5 Driving device 8 Friction member 8b Blocking piece 9 Storage case 9a, 9b Case half 9h Convex portion 10 Cam wheel 11 Drive mechanism 12 Switch mechanism 13 Motor 28 Ice detecting cam surface 29 Pressing member operating cam surface 31 Ice detecting shaft 31d Switch pressing operation blocking piece 41 Pressing member 42 Pressing switch 51 Circuit board 53a U-shaped groove (supporting portion)

Claims (4)

When an ice shortage in the ice storage container is detected, the ice making tray is inverted to drop the ice into the ice storage container, and then the ice making tray is returned to its original position to produce ice. A press switch that is pressed / non-pressed in response to the rotational drive of the ice tray, and the press switch has a surface opposite to the contact surface with the press member that presses the press switch. An automatic ice making machine characterized in that, by directly contacting an end face of a convex portion formed inside, this is used as a reference position in the height direction, and is arranged in the storage case based on the reference position. Drive device. 2. The drive device for an automatic ice maker according to claim 1, wherein the pressing member is rotatably supported by a support portion provided in the storage case. The pressing member is constantly urged in the direction of pressing the pressing switch, and in the storage case, the ice storage container performs ice detection by moving down into the ice storage container. An ice detecting shaft that rotates integrally with the member, the ice detecting shaft is rotatably supported by a support member formed in the storage case, and the ice detecting shaft rotates when the ice detecting shaft rotates by a predetermined angle or more. The driving device for an automatic ice maker according to claim 1 or 2, further comprising a blocking piece that operates the pressing member against an urging force and blocks the pressing operation of the pressing switch of the pressing member. . A circuit board is fixed to an end surface of a motor serving as a drive source of the ice tray, and the pressing switch is installed on the circuit board so that a pressing direction is parallel to the circuit board surface, and the motor is placed in the storage case. After the circuit board is placed at a predetermined position, the circuit board is stored in the housing by rotating the circuit board with a fixed portion to the motor as a base point so that the pressing switch is brought into contact with the end surface of the convex portion. 4. The automatic ice maker drive device according to claim 1, wherein the automatic ice maker drive device is disposed in a case.

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