JP5009728B2 - cabinet - Google Patents

Description

  The present invention relates to a cabinet that includes a sub-drawer that is pulled in conjunction with a main drawer and moves the sub-drawer in the closing direction by releasing the kinetic energy stored in the energy storage means.

  Conventionally, the drawer device provided in the cabinet includes a drawer (main drawer) and an inner drawer (sub drawer) provided above the drawer, and a permanent magnet is provided on the back of the drawer door, Permanent magnets are also provided on the front part of the inner drawer, and when the drawer is pulled out from the cabinet, the permanent magnets are magnetically attached to each other so that the inner drawer is pulled out in conjunction with the movement of the drawer. ing. A spring (energy storage means) is attached to the lower part of the rear end of the inner drawer. When the inner drawer is pulled out together with the drawer, the spring abuts against the back surface of the front plate of the cabinet body and is compressed. The kinetic energy that moves in the opening direction is accumulated in the spring, and when the drawer is pulled out from the pull-out limit of the inner drawer, the permanent magnets are separated from each other and the elastic force (action) that the spring expands is used. Thus, the inner drawer moves in the closing direction (see, for example, Patent Document 1).

Japanese Patent Laying-Open No. 2006-141796 (page 5, FIG. 3)

  However, in the drawer device described in Patent Document 1, since the inner drawer (sub drawer) is automatically moved in the closing direction, the user does not have to operate the inner drawer, and the usability is improved. However, when both drawers move in the open direction while being linked, the movement energy is stored in the spring (energy storage means), so when pulling out both drawers, the elastic force of the spring It must be pulled out with a force that resists (action), and the pulling-out operation cannot be performed smoothly. If the user releases his / her hand before the drawer and the inner drawer are separated, the spring will accumulate. Energy may be released and the drawer and the inner drawer may move in the closing direction, and the user always holds the drawer handle when taking out the contents in the inner drawer. Must Kere, there is a problem that storage of the inner drawer so would blocked the single hand of a user is less likely to take out.

  The present invention has been made paying attention to such problems, and in a cabinet in which the secondary drawer is moved in the closing direction by releasing the kinetic energy stored in the energy storage means, the main drawer and the secondary drawer. It is an object of the present invention to provide a cabinet in which the main drawer and the sub drawer do not move in the closing direction and the stored items in the sub drawer can be easily taken out.

In order to solve the above-mentioned problem, the cabinet according to claim 1 of the present invention includes:
A cabinet comprising: a main drawer; a subdrawer that is pulled in conjunction with the main drawer; and energy storage means for storing kinetic energy that moves the subdrawer in a closing direction,
The energy storage means stores the movement energy when the main drawer moves in the closing direction.
According to this feature, when the main drawer and the sub drawer are pulled out, the energy storage means does not cause any action on both drawers, so that the main drawer and the sub drawer are easily pulled out. Therefore, even when the main drawer and the sub drawer are interlocked, the user can release the main drawer, and the user can easily take out the stored items in the sub drawer using both hands. it can.

The cabinet according to claim 2 of the present invention is the cabinet according to claim 1,
The energy storage means holds the kinetic energy when the main drawer and the sub drawer are interlocked.
According to this feature, in a state where the main drawer and the sub drawer are interlocked, the kinetic energy stored in the energy storage means is not changed regardless of whether both drawers are moved in the opening direction or in the closing direction. It does not cause any effect on the drawers, and there is no possibility of releasing the accumulated kinetic energy, so that the drawer operation of both drawers can be easily performed.

The cabinet according to claim 3 of the present invention is the cabinet according to claim 1 or 2,
The energy storage means releases the kinetic energy after the main drawer is further pulled out from a pull-out limit position from which the sub-drawer is pulled out and the interlock between the main drawer and the sub-drawer is released. It is a feature.
According to this feature, in a state where the main drawer and the sub drawer are interlocked, the user can perform the drawer operation of both drawers while recognizing that the sub drawer does not move in the closing direction. When the user wants to move the sub-drawer in the closing direction, the main drawer should be pulled out further than the pull-out limit position of the sub-drawer, and the usability of the main drawer and the sub-drawer is improved.
If the main drawer and the secondary drawer are released and then the main drawer is pulled out a predetermined distance and then set so that the kinetic energy of the energy storage means is released, the linkage between both drawers is released. The user can easily recognize that the secondary drawer is at the drawer limit position, and the user can remove the main drawer immediately after the two drawers are disconnected. If the pulling-out operation is stopped, the secondary drawer can be used with the largest opening.

The cabinet according to claim 4 of the present invention is the cabinet according to any one of claims 1 to 3,
The energy storage means stores the movement energy by deforming an elastic body.
According to this feature, the energy storage means can be easily configured using the elastic body that can be deformed to store the movement energy.

The cabinet according to claim 5 of the present invention is the cabinet according to any one of claims 1 to 4,
The energy storage means is one of a rotation member provided rotatably, and a release rotation direction for releasing the movement energy and an accumulation rotation direction for storing the movement energy. And an urging member that urges to rotate in the direction, and includes switching means for switching between both the rotating directions.
According to this feature, the switching means switches the rotation urging direction of the rotation member by the urging member, so that the kinetic energy is stored in or released from the energy storage means. The energy storage means can be manufactured with a simple configuration of an urging member.

The cabinet according to claim 6 of the present invention is the cabinet according to any one of claims 1 to 5,
The main drawer and the sub drawer are interlocked with each other by an attractive force between magnetic bodies provided to each other.
According to this feature, it is possible to easily link and release the main drawer and the sub drawer by using the attractive force between the magnetic bodies only by providing the magnetic body in the main drawer and the sub drawer.

The cabinet according to claim 7 of the present invention is the cabinet according to claim 6,
The depth length of the sub-drawer is configured to be shorter than the depth length of the main drawer, and the main drawer and the sub-drawer are characterized in that their rear portions are connected to each other by the magnetic body.
According to this feature, a storage space that does not interfere with the sub-drawer is formed on the front side of the main drawer, and is stored on the front side of the main drawer without moving the sub-drawer in the closing direction. The stored items can be taken out, and tall items can be stored on the front side of the main drawer.

The cabinet according to claim 8 of the present invention is the cabinet according to any one of claims 1 to 7,
After the energy storage means stores the moving energy, the main drawer includes a speed reduction means for reducing the moving speed at which the main drawer moves in the closing direction.
According to this feature, since the kinetic energy for moving the main drawer in the closing direction is not reduced by the deceleration means, the kinetic energy can be stored in the energy storage means, so that it is easy to store large kinetic energy, Moreover, the movement of the main drawer can be smoothly stopped by the deceleration means when the main drawer is closed.

  The best mode for carrying out the cabinet according to the present invention will be described below based on examples.

  An embodiment of the present invention will be described with reference to the drawings. First, FIG. 1 is a perspective view showing an overall image of a cabinet in the embodiment 1, and FIG. 2 shows a main drawer and a sub-drawer accommodated in the cabinet body. FIG. 3 is an enlarged longitudinal sectional side view showing a state, FIG. 3 is an enlarged longitudinal sectional side view showing a state in which the sub-drawer is pulled out to a withdrawal limit position, and FIG. FIG. 5 is an enlarged vertical side view showing a state, FIG. 5 is an enlarged vertical side view showing a state in which the sub-drawer is retracted by operating the spring mechanism, and FIG. 6 is when moving the main drawer backward. FIG. 7 is an enlarged vertical side view showing a state in which the trigger pin is engaged with the spring mechanism, and FIG. 7 is an enlarged vertical side view showing a state in which energy is accumulated in the spring mechanism and the soft closer is operated. Is the main drawer FIG. 8B is a cross-sectional plan view showing a state in which the trigger pin engages with the cam of the spring mechanism at the time of ejection, and FIG. 8B is a cross-sectional plan view showing a state in which the spring mechanism is operated and biased backward; FIG. 8C is a transverse plan view showing a state where the spring mechanism is retracted, and FIG. 9A is a transverse plan view showing a state where the trigger pin is engaged with the cam of the spring mechanism when the main drawer is closed. FIG. 9B is a transverse plan view showing a state where energy is accumulated in the spring mechanism, and FIG. 9C is a transverse plan view showing a state where energy is completely accumulated in the spring mechanism. . Hereinafter, the left side of FIG. 2, FIG. 3, FIG. 4, FIG. 5, FIG. 6 and FIG. 7 is the front side (front side) of the cabinet, and the lower side of FIG. This will be described as the front side.

  Reference numeral 1 in FIG. 1 denotes a cabinet to which the present invention is applied. The cabinet 1 can accommodate a wide variety of documents, tableware, daily miscellaneous goods, and the like. The cabinet 1 has a cabinet body 2 having an opening opening on the front side, and a plurality (two) of main drawers 3 are provided in the opening of the cabinet body 2. A sub drawer 4 is provided in the main drawer 3.

  As shown in FIG. 2, the main drawer 3 is composed of a storage box 5 housed in the cabinet body 2 and a front plate 6 having a handle 7 held by a user. The storage box 5 is formed in a substantially box shape having a storage portion 5a opened upward (see FIG. 1).

The main drawer 3, between a storage position in the main drawer 3 is housed in the cabinet body 2 (closed), the main drawer 3 is withdraw limit position S ₁ of the main drawer to be pulled out to the limit on the front side, It can be moved in the front-rear direction (see FIG. 5). Incidentally, the front plate 6 of the main drawer 3 is formed in such a size that the sub drawer 4 is concealed from the front in a state where the main drawer 3 is housed in the cabinet body 2.

  Above the storage portion 5a of the main drawer 3, a sub drawer 4 having a substantially box-shaped storage box body 8 provided with a storage portion 8a opening upward is provided (see FIG. 1). Note that the weight of the sub drawer 4 is formed lighter than the weight of the main drawer 3, and the depth length of the sub drawer 4 is shorter than the depth length of the main drawer 3.

The sub drawer 4, as well as the main drawer 3, back and forth between a storage position of the sub-drawer 4 in the cabinet main body 2, the sub-drawer 4 is a withdraw limit position S ₂ of the sub-drawer drawn to the limit on the front side It can be moved in the direction (see FIG. 3).

  A space 9 (storage space) having a predetermined front-rear width is provided between the back side of the front plate 6 of the main drawer 3 and the front side of the storage box 8 of the sub-drawer 4. By providing the space portion 9, a tall storage item can be stored on the front side of the main drawer 3.

  In the present embodiment, the right side of the cabinet 1 means the right side when the user stands in front of the cabinet 1, and the left side of the cabinet 1 means that the user stands on the left side while standing in front of the cabinet 1. Explained.

As shown in FIG. 1, a slide rail 10 that slides the main drawer 3 in the front-rear direction is provided between the left and right side portions 5 b of the main drawer 3 and the side plate 2 a of the cabinet body 2. This slide rail 10, the main drawer 3, between the withdraw limit position S ₁ of the storage position and the main drawer main drawer 3, the opening direction (front direction) and to be able to move freely in the closing direction (rear direction) (See FIG. 5).

  Further, as shown in FIG. 2, at the rear end portion of the slide rail 10, when the main drawer 3 is stored in the cabinet body 2, the deceleration in the present embodiment for reducing the moving speed of the main drawer 3. A soft closer 11 (buffer device) is provided as a means.

  Further, as shown in FIG. 2, a permanent magnet 13 (magnetic material) attracted by a metal piece 12 (magnetic material) of the sub-drawer 4 described later is disposed on the back side of the back plate 5c of the storage box 5 of the main drawer 3. ) Is provided. Further, a trigger pin 14 as a switching means in this embodiment is erected on the upper end portion of the back plate 5c toward the sub drawer 4 (see FIG. 8A).

As shown in FIG. 1, a slide rail 15 is provided between the left and right side portions 8 b of the sub-drawer 4 and the side plate 2 a of the cabinet body 2 in the same manner as the main drawer 3. This by the slide rail 15, the sub-drawer 4, between the withdraw limit position S ₂ of the storage position and vice drawer sub drawer 4, can move in the longitudinal direction.

Further, a soft closer 11 is provided at the rear end of the slide rail 15 in the same manner as the slide rail 10. As shown in FIGS. 3 and 5, the distance from the front side of the cabinet body 2 distance to withdraw limit position S ₁ of the main drawer until withdraw limit position S ₂ of the sub-drawer from the front side of the cabinet body 2 Longer than.

  As shown in FIG. 2, a metal piece 12 as a magnetic body in the present embodiment extends downward at the rear end portion of the sub-drawer 4, and this metal piece 12 is the main drawer 3 described above. The permanent magnet 13 is attracted. When the permanent magnet 13 and the metal piece 12 are attracted and joined to each other, the main drawer 3 and the sub drawer 4 are connected to each other, and the main drawer 3 is pulled out from the cabinet body 2. Then, the sub drawer 4 is pulled out of the cabinet body 2 in conjunction with the main drawer 3.

  Further, as shown in FIGS. 1 and 2, a spring mechanism 16 as an energy storage unit in the present embodiment is provided on the right side of the lower surface of the sub drawer 4. As shown in FIG. 8A, the spring mechanism 16 has a case body 17 having a thin box shape in which an opening 17b communicating with the outside is formed on the left side. A cam 18 as a rotating member in the present embodiment is disposed, and the case body 17 is formed with a shaft hole 17a that supports the shaft 18a of the cam 18.

  The cam 18 is formed in a substantially semicircular shape in plan view, and a shaft 18a is provided at the center of the semicircle. Further, a part of the cam 18 protrudes from the opening 17b of the case body 17 to the outside. Furthermore, a spring 19 (coil spring) is provided as an elastic body and a biasing member in this embodiment for biasing the cam 18 in rotation. Further, a stopper 20 having a circular shape in a plan view is erected on the lower surface of the inner wall of the case body 17.

  Further, an engagement groove 18b is formed from the end edge portion forming the arc of the cam 18 to the radial direction so that the trigger pin 14 of the main drawer 3 is engaged. As will be described later, the engagement groove 18b has a predetermined length in the radial direction so that the trigger pin 14 fixed to the main drawer 3 can maintain the engagement state.

  Further, the cam 18 is formed with a regulation groove 18c having a substantially arc shape in a plan view through which the stopper 20 is inserted. The rotation range of the cam 18 is regulated by arranging the stopper 20 in the regulation groove 18c. In addition, by restricting the rotation range of the cam 18, the engagement groove 18 b always protrudes from the opening 17 b of the cam 18 to the outside of the case body 17.

  As shown in FIG. 8C, a locking portion 18d for locking the spring 19 is provided between the shaft 18a and the regulating groove 18c on the upper surface side (front side of the paper) of the cam 18, and the case At the right rear end portion of the body 17, a locking portion 17 c that similarly locks the spring 19 is provided. A spring 19 is stretched between the locking portions 17c and 18d. The spring 19 is stretched and elastically deformed to accumulate its elastic force, and is compressed and elastically restored to release the elastic force.

  As shown in FIG. 8A, the rotating direction in which the spring 19 is compressed from the extended state of the spring 19 as shown in FIG. 8C, that is, the cam 18 in a plan view. A rotation direction that rotates counterclockwise is referred to as a release rotation direction. Furthermore, as shown in FIG. 9A, the rotating direction in which the spring 19 is expanded from the compressed state of the spring 19 as shown in FIG. 9C, that is, the cam 18 is seen in a plan view. The rotation direction that rotates clockwise is referred to as the accumulation rotation direction.

  As shown in FIGS. 9A to 9C, when the trigger pin 14 is engaged with the engagement groove 18b of the cam 18 of the spring mechanism 16, the cam 18 is rotated in the accumulation rotation direction. Since the locking portion 18d provided on the upper surface of the cam 18 also rotates in the accumulation rotation direction, the spring 19 urges the cam 18 to rotate in the accumulation rotation direction with the locking portion 17c as a fixed end. . Along with this, the spring 19 expands and elastic energy is accumulated.

As shown in FIG. 9C, the stopper 20 engages the restriction groove 18c, so that the rotation of the cam 18 in the accumulation rotation direction is stopped. At this time, the spring 19, by the action restoring force to be compressed to the original length by being stretched is, the locking portion 18d exceeds the imaginary line V ₁ connecting the engaging portion 17c and the shaft 18a located Since the rotation of the cam 18 is stopped, the restoring force of the spring 19 urges the cam 18 in the accumulation rotation direction, and the spring 19 is held in an expanded state, that is, in a state where elastic energy is accumulated. Is done.

  As shown in FIGS. 8A to 8C, when the trigger pin 14 is engaged with the engagement groove 18b of the cam 18 of the spring mechanism 16, the cam 18 is rotated in the release rotation direction. Then, the locking portion 18d provided on the upper surface of the cam 18 also rotates in the releasing rotation direction, so that the spring 19 rotates and biases the cam 18 in the releasing rotation direction with the locking portion 17c as a fixed end. . Accordingly, the spring 19 is compressed and the elastic energy is released.

At this time, exceeds a virtual line V ₁ which locking portion 18d is connecting the engaging portion 17c and the shaft 18a, releasing rotation of the restoring force in a direction that the cam 18 of the spring 19 which was working storage rotational direction of the cam 18 Since the direction is switched, the spring 19 returns to the original compressed length as shown in FIG. 8C while rotating the cam 18 in the releasing rotation direction by the restoring force.

As will be described later, a predetermined interval is formed between the spring mechanism 16 and the metal piece 12. By the slide rail 15 of the sub-drawer 4 is pulled out to the limit, the trigger sub drawer is pulled out to withdraw limit position S _2, the main drawer 3 and the connecting sub drawer 4 is released, provided in the main drawer 3 The pin 14 is configured to engage with the engagement groove 18 b of the cam 18 of the spring mechanism 16 after moving a predetermined distance between the spring mechanism 16 and the metal piece 12.

  As shown in FIG. 2, when the user holds the handle 7 and pulls it out to the front side while being stored in the storage position in the cabinet 1, as shown in FIG. The sub drawer 4 is pulled out in a state where it is connected by a permanent magnet 13 and a metal piece 12 provided at the rear of each.

  The spring 19 in the spring mechanism 16 at this time is in a state where energy has already been accumulated as shown in FIG. 8A, but the main drawer 3 and the sub drawer 4 are interlocked. Therefore, the trigger pin 14 is not engaged, and the spring 19 is held in a state where energy is accumulated.

As shown in FIG. 3, when the user continues to further pull the main drawer 3 on the front side, the main drawer 3 is interlocked with drawn by that sub-drawer 4 reaches the withdraw limit position S ₂ of the sub-drawer. At this time, the force with which the user pulls out the main drawer 3 to the front side works in a direction to release the magnetized state of the permanent magnet 13 and the metal piece 12, so the user magnetizes the permanent magnet 13 and the metal piece 12. sensing a suction force as a resistance, can be sub-drawer 4 recognizes that it has reached the withdraw limit position S ₂ of the sub-drawer. Incidentally, when the user uses the sub drawer 4, it is possible to use this auxiliary drawer 4 is the most accommodating portion 8a is when it reaches the withdraw limit position S ₂ of the sub-drawer large opening to, housing Objects can be taken out and stored easily.

  Further, when the user uses the main drawer 3, the main drawer 3 is further pulled out from the state shown in FIG. 3 to release the magnetic adhesion between the permanent magnet 13 and the metal piece 12, and the main drawer 3 And the secondary drawer 4 are released. Then, as shown in FIG. 4, the trigger pin 14 provided on the main drawer 3 is pulled by the user pulling the main drawer 3 to the front side from the state where the interlocking of the main drawer 3 and the sub drawer 4 is released. It engages with an engagement groove 18 b of a spring mechanism 16 provided on the lower surface of the sub drawer 4. It should be noted that the user can use the sub-drawer 4 even if the magnetism between the permanent magnet 13 and the metal piece 12 is released before the trigger pin 14 is engaged with the engagement groove 18b.

  Then, as shown in FIGS. 4 and 8A, when the user further pulls out the main drawer 3 to the front side, the trigger pin 14 provided on the main drawer 3 engages with the engagement groove 18b. Thus, the trigger pin 14 rotates the cam 18 in the release rotation direction.

As shown in FIG. 8 (b), to a position beyond the imaginary line V ₁ to the position of the locking portion 17c is connecting the axial 18a and the locking portion 18 d, the trigger pin 14 rotates in the releasing rotational direction of the cam 18 Then, the spring 19 is compressed, the elastic energy accumulated in the spring 19 is released, and the spring 19 forcibly rotates the cam 18.

  Further, as shown in FIGS. 8B to 8C, the cam 18 is forcibly rotated in the release rotation direction by the spring 19, so that the rotational force of the cam 18 causes the trigger pin 14 to face the front. It works to press to the side. At this time, the weight of the sub drawer 4 is lighter than the weight of the main drawer 3, and the main drawer 3 is gripped by the user 7 so that the cam 18 presses the trigger pin 14 to the front side. Due to the reaction force, the sub-drawer 4 is moved in the closing direction (rearward direction).

  As shown in FIG. 5, the sub-drawer 4 provided with the spring mechanism 16 is given kinetic energy by the urging force of the spring 19 and moves to the storage position in the cabinet body 2. The secondary drawer 4 is decelerated by the soft closer 11 provided at the rear end of the slide rail 15 in the vicinity of the storage position, and the movement of the secondary drawer 4 is smoothly stopped when the closing is completed.

After the sub-drawer 4 is moved to the storage position in the cabinet body 2, main drawer 3 is pulled out to the withdraw limit position S ₁ of the main drawer, a state in which housing part 5a has the largest open upward, the user The stored items in the main drawer 3 can be easily taken in and out.

When moving from the withdraw limit position S ₁ of the main drawer main drawer 3 in the storage position in the cabinet body 2, first, the main drawer 3 the closing direction by gripping the handle 7 user from a state shown in FIG. 5 ( Move backward).

  As shown in FIGS. 6 and 9A, when the main drawer 3 is moved in the closing direction, the trigger pin 14 is engaged with the engagement groove 18 b of the cam 18 of the spring mechanism 16. Then, as shown in FIG. 9B, the main drawer 3 is further moved in the closing direction (rearward direction) with the trigger pin 14 engaged with the engagement groove 18b, so that the cam 18 is moved by the trigger pin 14. It is rotated in the accumulation rotation direction. Thus, the kinetic energy when moving in the closing direction of the main drawer 3 is converted and accumulated as elastic energy that is elastically deformed by the extension of the spring 19 by the rotation of the cam 18.

Then, as shown in FIG. 7 and FIG. 9 (c), the be to further move the main drawer 3 in the closing direction (rear direction), the accumulation rotated to the engaging portion 18d of the cam 18 exceeds the imaginary line V ₁ The spring 19 accumulates movement energy.

  Further, as shown in FIG. 7, after the movement energy is accumulated in the spring mechanism 16, the main drawer 3 is decelerated by the soft closer 11 provided at the rear end portion of the slide rail 10, and the main drawer is smoothly pulled out when the closing is completed. The movement of 3 is stopped. The main drawer 3 stops at the storage position in the cabinet body 2, and the permanent magnet 13 of the main drawer 3 is magnetically attached to the metal piece 12 of the sub drawer 4, so that the main drawer 3 and the sub drawer 4 are connected.

  As described above, in the kitchen cabinet 1 according to the present embodiment, the spring mechanism 16 as the energy storage means draws out the main drawer 3 and the sub drawer 4 by storing the movement energy when the main drawer 3 moves in the closing direction. In some cases, the spring mechanism 16 does not generate any repulsive force with respect to the drawers 3 and 4, so that the main drawer 3 and the subdrawer 4 can be easily pulled out. Therefore, even in a state where the main drawer 3 and the sub drawer 4 are interlocked, the user can release his / her hand from the main drawer 3 and the stored items in the sub drawer 4 can be easily taken out.

  Further, when the main drawer 3 and the sub drawer 4 are interlocked with each other, the spring mechanism 16 as the energy storage means holds the moving energy when the main drawer 3 and the sub drawer 4 are interlocked. Regardless of whether the drawers 3 and 4 are moved in the opening direction or in the closing direction, the kinetic energy accumulated in the spring mechanism 16 is accumulated without causing any repulsive force on the drawers 3 and 4. Since there is no possibility of releasing the moving energy, it becomes easy to perform the drawer operation of both drawers 3 and 4.

Further, the main drawer 3, after the interlocking of the sub-drawer 4 is further withdrawn than withdraw limit position S ₂ to be pulled out as the main drawer 3 and the sub drawer 4 is released, the spring mechanism 16 as an energy storage means, By releasing the kinetic energy, in the state where the main drawer 3 and the sub drawer 4 are interlocked, the user recognizes that the sub drawer 4 does not move in the closing direction, 4 pulled out can be performed for, and the user, when it is desired to move the sub-drawer 4 in the closing direction, if the main drawer 3 so as to further draw than withdraw limit position S ₂ of the sub-drawer 4 The usability of the main drawer 3 and the sub drawer 4 is improved.

If the main drawer 3 and the sub-drawer 4 are released from being interlocked and then the main drawer 3 is pulled out by a predetermined distance and then set so that the kinetic energy of the spring mechanism 16 as the energy storage means is released. by user that interlocking is released both drawers 3,4 are recognized, the user can by-drawer 4 easily recognize that in the extended limit position S _2, the user, If the operation of pulling out the main drawer 3 is stopped immediately after the connection between the two drawers 3 and 4 is released, the sub-drawer 4 can be used with the largest opening.

  Further, the spring mechanism 16 as the energy storage means can easily configure the energy storage means by storing the kinetic energy by deforming the spring 19 as an elastic body.

  Further, the spring mechanism 16 as energy storage means includes a cam 18 as a rotation member provided rotatably, and a release rotation direction for releasing the movement energy, or storage for storing the movement energy. A spring 19 as an urging member that urges rotation in any one of the rotation directions, and the main drawer 3 includes a trigger pin 14 as switching means for switching between both rotation directions. The trigger pin 14 switches the rotational biasing direction of the cam 18 by the spring 19, so that the kinetic energy is stored in or released from the spring mechanism 16, and the cam 18 and the spring 19 have a simple configuration. The spring mechanism 16 can be manufactured.

  Further, the main drawer 3 and the sub drawer 4 are interlocked by the attraction force of the metal piece 12 and the permanent magnet 13 as magnetic bodies provided to each other, thereby utilizing the attraction force of the metal piece 12 and the permanent magnet 13. Thus, the main drawer 3 and the sub drawer 4 can be easily linked and released.

  Moreover, the depth length of the sub drawer 4 is configured to be shorter than the depth length of the main drawer 3, and the main drawer 3 and the sub drawer 4 are composed of a metal piece 12 and a permanent magnet 13, each of which has a rear portion. By being connected, a space portion 9 as a storage space that is not interfered by the sub drawer 4 is formed on the front side of the main drawer 3, and the main drawer 3 is not moved in the closing direction. The stored items stored on the front side of the drawer 3 can be taken out, and the tall stored items can be stored on the front side of the main drawer 3.

  Further, after the spring mechanism 16 as the energy storage means accumulates the movement energy, the main drawer 3 is provided with the soft closer 11 as a deceleration means for decelerating the moving speed at which the main drawer 3 moves in the closing direction. Since the moving energy can be stored in the spring mechanism 16 in a state where the moving energy that is moved to is not reduced by the soft closer 11, it is easy to store a large amount of moving energy, and the soft drawer 11 closes the main drawer 3. When completed, the movement of the main drawer 3 can be stopped smoothly.

  Next, a cabinet according to the second embodiment will be described with reference to FIGS. In addition, the same structure as the said Example is abbreviate | omitted. FIG. 10 is an enlarged vertical side view showing a state in which the trigger pin is engaged with the cam of the weight mechanism when the main drawer is pulled out in the second embodiment, and FIG. 11 is urged backward by the weight mechanism operating. It is an expanded vertical side view which shows a state. Hereinafter, the left side of FIG. 10 and FIG. 11 will be described as the front side (front side) of the cabinet.

  As shown in FIG. 10, the weight mechanism 21 as energy storage means in the second embodiment is provided below the slide rail 15 on the left and right side portions 8 b of the sub drawer 4. Further, unlike the spring 19 of the spring mechanism 16 of the first embodiment, the weight mechanism 21 of the second embodiment uses a weight 23 as means for accumulating kinetic energy. The weight 23 is an urging member in the second embodiment.

  More specifically, the weight mechanism 21 as energy storage means is a rotating member in the present embodiment in which a weight 23 is integrally provided at an end portion within a case body 25 having an opening 25b in the lower part (downward in the drawing). A cam 22 is pivotally supported. In the second embodiment, the kinetic energy for moving the sub drawer 4 in the closing direction is stored as the potential energy of the weight 23 of the weight mechanism 21.

As shown in FIG. 10, the cam 22 of the weight mechanism 21 is configured such that when the weight 23 is on the front side of the virtual vertical line V ₂ that extends vertically through the shaft 22 b of the cam 22, the weight 23 moves the cam 22. Rotation bias is applied in the accumulation rotation direction (counterclockwise in side view) The rotation of the cam 22 is restricted by the stopper 20, and the cam 22 can accumulate the potential energy of the weight 23. Further, as shown in FIG. 11, when the weight 23 is in the rear side of the imaginary vertical line V ₂ is the weight 23 so as to urge rotation (clockwise as viewed from the side) release the rotational direction of the cam 22 It has become.

  Further, the trigger pin 24 as the switching means in the present embodiment provided at the rear end portion of the main drawer 3 is erected from the rear end portion of the main drawer 3 and bent horizontally. It has a letter shape. An end portion of the trigger pin 24 can be engaged with an engagement groove 22 a formed in the cam 22 of the weight mechanism 21.

As shown in FIG. 10, when releasing the potential energy when the weight mechanism 21 is located on the front side of the virtual vertical line V ₂ , that is, when the potential energy is accumulated in the weight mechanism 21. First, by pulling out the main drawer 3, the trigger pin 24 provided on the main drawer 3 is engaged with the engagement groove 22a of the cam 22. Then, when the user pulls out the main drawer 3, the cam 22 starts to rotate in the release rotation direction.

As shown in FIG. 11, the cam 22 is rotated in the release rotation direction by the trigger pin 24, and when the weight 23 comes behind the virtual vertical line V ₂ by this rotation, the weight 23 forces the cam 22. Trying to rotate in the release rotation direction. Then, the potential energy of the weight 23 forcibly rotates the cam 22 in the releasing rotation direction, so that the rotational force of the cam 22 works to press the trigger pin 24 to the front side. When the cam 22 presses the trigger pin 24 to the front side, the sub drawer 4 is moved in the closing direction (rear direction).

In order to accumulate the potential energy in the weight mechanism 21 again, when the main drawer 3 pulled out is moved to the storage position in the cabinet body 2, the trigger pin 24 is engaged with the engagement groove 22a as shown in FIG. , The cam 22 is rotated in the accumulation rotation direction, the weight 23 is moved to the front side of the virtual vertical line V ₂ , and the movement energy in the closing direction of the main drawer 3 is reduced by the weight mechanism 21. Accumulated as potential energy of the weight 23.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the first and second embodiments, the main drawer 3 and the sub drawer 4 are connected by magnetizing a permanent magnet 13 and a metal piece 12 as a magnetic material. It is not always necessary to use a magnetic material in order to connect (link) 4 to 4, and a joint member comprising a male tool and a female tool is provided on the main drawer 3 and the sub drawer 4 to connect the male tool and the female tool. However, the separation may be performed when a required external force is applied.

  In the first and second embodiments, the permanent magnet 13 is provided at the upper rear end of the main drawer 3 and the metal piece 12 is provided at the lower rear end of the sub drawer 4, but for example, the side 5b of the main drawer 3 is provided. In addition, a permanent magnet 13 may be provided in the middle and a metal piece 12 may be provided in the lower part of the front end of the sub drawer 4, and the depth length of the sub drawer 4 may be substantially the same as the depth length of the main drawer 3. In addition, the permanent magnet 13 may be provided at the upper part of the front end of the main drawer 3 and the metal piece 12 may be provided at the lower part of the front end of the sub drawer 4, and the permanent magnet 13 and the metal piece 12 may be provided in the main drawer 3 and the sub drawer 4. The position to be provided is not particularly limited.

  In the first and second embodiments, the permanent magnet 13 is provided in the main drawer 3 and the metal piece 12 is provided in the sub drawer 4, but permanent magnets having different polarities are used for the main drawer 3 and the sub drawer 4, respectively. Alternatively, a metal piece may be provided on the main drawer 3 and a permanent magnet may be provided on the sub drawer 4.

  In the first embodiment, the spring 19 is used as an elastic body for accumulating kinetic energy. However, the elastic body is not limited to the spring 19 and may be a fluid having elasticity such as air in an air damper. Good.

  In the first embodiment, the spring mechanism 16 stores the elastic energy by extending the spring 19. However, the spring mechanism 16 may compress the spring 19 to store the elastic energy. .

  In the first and second embodiments, after the main drawer 3 and the sub-drawer 4 are disengaged, the main drawer 3 is pulled out by a predetermined distance, and then the kinetic energy accumulated in the spring mechanism 16 is released. However, the movement energy may be released at the same time as the interlocking between the main drawer 3 and the sub drawer 4 is released.

  In the first and second embodiments, the main drawer 3 is provided with the trigger pin 14 (24) as the switching means, and after the interlock of the main drawer 3 and the sub drawer 4 is released, the spring mechanism as the energy storage means. The movement energy accumulated in 16 (weight mechanism 21) is released, but a trigger pin as a switching means is provided on the side plate 2a of the cabinet body 2, a switch for pressing the switching means by the user instead of the trigger pin, etc. By configuring as above, the kinetic energy of the energy storage means may be released before the interlocking of the main drawer 3 and the sub drawer 4 is released.

  In the first embodiment, the depth of the sub drawer 4 is shorter than the depth of the main drawer 3, and the space formed between the rear surface of the front plate 6 of the main drawer 3 and the front surface of the front end of the sub drawer 4. Although it is possible to store a tall storage item in the portion 9, the main drawer 3 and the sub drawer 4 are formed to have substantially the same depth length, and the main drawer 3 and the sub drawer 4 are interlocked. The storage portion 5a of the main drawer 3 may be concealed by the sub drawer 4.

  In the first embodiment, the trigger pin 14 is engaged with the engagement groove 18 b of the cam 18 and the cam 18 is rotated. However, a rack gear is provided on the main drawer 3, and a tooth profile is formed on the edge of the cam 18. The cam 18 may be rotated by meshing the teeth formed on the rack gear and the cam 18.

It is a perspective view which shows the whole image of the cabinet in Example 1. FIG. It is an expanded vertical side view which shows the state by which the main drawer and the sub drawer were accommodated in the cabinet main body. It is an expanded vertical side view which shows the state by which the sub drawer was pulled out to the drawer limit position. It is an enlarged vertical side view showing a state where the trigger pin of the main drawer is engaged with the spring mechanism. It is an expanded vertical side view which shows the state which the spring mechanism act | operated and the subdrawer retracted. It is an expanded vertical side view which shows the state which a trigger pin engages with a spring mechanism when moving a main drawer toward back. It is an expanded vertical side view which shows the state by which energy is accumulate | stored in a spring mechanism and a soft closer works. (A) is a cross-sectional top view which shows the state which a trigger pin engages with the cam of a spring mechanism at the time of extraction | drawer of a main drawer, (b) shows the state which a spring mechanism operate | moves and is urged | biased back. It is a cross-sectional plan view, (c) is a cross-sectional plan view showing a state in which the spring mechanism is retracted. (A) is a cross-sectional plan view showing a state where the trigger pin is engaged with the cam of the spring mechanism when the main drawer is closed, and (b) is a cross-sectional plan view showing a state where energy is stored in the spring mechanism. (C) is a cross-sectional plan view showing a state where energy has been accumulated in the spring mechanism. It is an expanded vertical side view which shows the state which a trigger pin engages with the cam of a weight mechanism at the time of the drawer of the main drawer in Example 2. FIG. It is an expanded vertical side view which shows the state by which a weight mechanism operate | moves and is urged | biased back.

Explanation of symbols

1 Cabinet 2 Cabinet body 3 Main drawer 4 Sub drawer 9 Space (storage space)
11 Soft closer (deceleration means)
12 Metal pieces (magnetic material)
13 Permanent magnet (magnetic material)
14 Trigger pin (switching means)
16 Spring mechanism (energy storage means)
18 Cam (Rotating member)
19 Spring (elastic body, biasing member)
21 Weight mechanism (energy storage means)
22 Cam (Rotating member)
23 weight (biasing member)
24 Trigger pin (switching means)

Claims (8)

A cabinet comprising: a main drawer; a subdrawer that is pulled in conjunction with the main drawer; and energy storage means for storing kinetic energy that moves the subdrawer in a closing direction,
The cabinet according to claim 1, wherein the energy storage means stores the movement energy when the main drawer moves in a closing direction.   2. The cabinet according to claim 1, wherein the energy storage means holds the kinetic energy when the main drawer and the sub drawer are interlocked.   The energy storage means releases the kinetic energy after the main drawer is further pulled out from a pull-out limit position from which the sub-drawer is pulled out and the interlock between the main drawer and the sub-drawer is released. The cabinet according to claim 1 or 2, characterized in that   The cabinet according to any one of claims 1 to 3, wherein the energy storage means stores the movement energy by deforming an elastic body.   The energy storage means is one of a rotation member provided rotatably, and a release rotation direction for releasing the movement energy and an accumulation rotation direction for storing the movement energy. The cabinet according to any one of claims 1 to 4, further comprising a switching unit that switches between the two rotation directions.   The cabinet according to any one of claims 1 to 5, wherein the main drawer and the sub drawer are interlocked by an attractive force between magnetic bodies provided to each other.   The depth length of the sub-drawer is configured to be shorter than the depth length of the main drawer, and the main drawer and the sub-drawer are connected to each other at their rear portions by the magnetic body. The cabinet according to 6.   The cabinet according to any one of claims 1 to 7, further comprising a decelerating unit that decelerates a moving speed at which the main drawer moves in a closing direction after the energy accumulating unit accumulates the moving energy.

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