KR20130138069A - Cabinet of elevating type - Google Patents

Abstract

The present invention relates to an elevatable cabinet and, specifically, to a technology which reduces the failure rate of a cabinet; which facilitates manufacturing and maintenance for a cabinet by simplifying the structure in comparison with conventional cabinets; which prevents damage to an elevation structure caused by weight loads by stabilizing elevation for a cabinet in comparison with conventional cabinets; and which prevents products from being unnecessarily enlarged by eliminating unnecessary spaces relating the elevation structure.

Description

Lift type cabinet {CABINET OF ELEVATING TYPE}

The present invention relates to a storage cabinet used in the kitchen, and more particularly, to allow the entire storage cabinet to be moved up and down to facilitate the storage of the stored article, and relates to a technology that can simplify the lifting structure and stable lifting as compared to the conventional.

In general, kitchens such as homes and restaurants are installed in several places such as sinks.

In most home kitchens, cabinets are installed above the sinks, which are located at a higher point than most cabinets in consideration of the distance from the sink water valves.

Therefore, people who have a small height, such as women or children, is very inconvenient to use the cabinet, so often use a chair or the like.

Recently, a technique for solving such a problem has been proposed.

This prior art is a technique which makes it possible to raise and lower the cabinet while the cabinet is accommodated in the case.

However, this prior art is a structure in which the cabinet is connected to the case through a plurality of links and withdrawn and lifted by the rotation of each link, such a link structure is difficult to manufacture and difficult to produce due to the complex structure of the link is used Not only is it large, but it is difficult to maintain.

In addition, the cabinet is moved while forming an arc of a certain trajectory during the elevation process. In this case, both the weight of the cabinet and the weight of the article are concentrated on the link, and the link structure has a high bearing capacity due to its structural characteristics. Due to this, there is also a problem in that a phenomenon such as breakage of the link between each link is easily generated.

In addition, in the structure in which several links are connected, the power transmission structure generated from the driving motor has a complicated disadvantage.

In addition, as the above cabinet ascends to form an arc, as the movement radius is large, it is inconvenient to use, and also has a problem in that the weight load of the cabinet acts more greatly.

In addition, since the cabinet is moved in this arc shape, a space must be secured between the case and the upper surface of the cabinet to prevent mutual collisions. However, the space formed between the cabinet and the case is formed only to prevent the collision, but does not have a storage function at all because of this has the disadvantage that the overall product size unnecessarily large.

In addition, since the installation space for link installation must be secured between both side walls of the cabinet and both side walls of the case, the size of the product is adversely affected.

Republic of Korea Patent Publication No. 10-0377118 Japanese Laid-Open Patent Publication No. 1995-303534

The present invention has been proposed in order to solve the problems of the prior art,

Basically, by simplifying the lifting structure of the cabinet compared to the existing, it is easy to manufacture and minimize the possibility of failure, as well as provide a lifting cabinet that can be easily maintained.

In addition, by allowing the cabinet to be lifted more stably than the conventional, to provide a lift-type cabinet that can prevent damage of the lifting structure by the weight load.

In addition, to prevent the unnecessary space associated with the lifting structure to provide a lifting type cabinet that can prevent the phenomenon that the size of the product unnecessarily large.

To this end,

A case having an open front and a lower part and having an installation space formed therein, a storage cabinet which is accommodated to be withdrawn in the installation space and has a storage space formed therein, a drive motor located in the installation space, and an inside of the case A rotary screw rod positioned between a surface and a side wall of the cabinet, the rear end being rotatably connected to the driving motor, and positioned in an inclined downward direction toward the front end, and formed on the side wall of the cabinet and the rotary screw rod It is fastened to the rotating screw rod includes a moving guide member capable of linear movement along the longitudinal direction of the rotating screw rod.

The rotating screw rod and the moving guide member may be formed on both side walls of the cabinet.

In addition, the inner side of the case is formed with a guide rail inclined in the same manner as the rotary screw rod, the movement guide member may be movable along the longitudinal direction of the guide rail in the state inserted into the guide rail.

And one of the inner surface of the case and the side wall of the cabinet may be formed a support rail of the same inclination shape as the rotating screw rod, is connected to the other of the inner side of the case and the side wall of the cabinet It may further include a support member inserted into the support rail and movable in the longitudinal direction of the support rail.

In addition, the drive motor is connected to any one of each of the rotary screw rod, the power transmission unit for connecting the rotary screw rod and the other rotary screw rod located on the opposite side to transfer the rotational force of the rotary screw rod to the other rotary screw rod It may include.

Further, at least one of the inner and outer circumferential surfaces of the case may be further provided with a separate reinforcement frame for preventing the bending of the case.

The present invention having these various embodiments,

As the cabinet is elevated in a straight direction along the longitudinal direction of the rotating screw rod along with the moving guide member when the rotating screw rod is rotated, the lifting structure of the cabinet is simpler than before, making production easier and minimizing the possibility of failure and maintenance. It has the advantage of being easier.

In addition, since the rotating screw rod and the moving guide member are operated at the same time in the state located on both sides of the cabinet has the advantage that the cabinet can be lifted stably.

In addition, since the movable member is moved together with the cabinet in the state inserted into the guide rail of the case, the movable member and the guide rail serve to support the weight load of the cabinet, so that the stable lifting can be induced.

In addition, as the support rail and the support member connected thereto are further installed, the support rail may further increase the support effect of the storage closet during the lifting movement of the storage closet.

In addition, since the driving motor is connected to only one of the two rotating screw rods, the rotational force of the rotating screw rod is transmitted to the opposite rotating screw rod through the power transmission unit, so that the economic effect of installing the driving motor can be obtained and the space consumption can be minimized. .

In addition, since the rotation speed of both the rotating screw rods is the same, there is an advantage that the stable lifting is possible because the occurrence of deviation of both driving forces is prevented during the lifting of the cabinet.

In addition, by installing a separate reinforcing frame on the inner or outer circumferential surface of the case, even if the lower part of the case is opened, there is an advantage that the bending phenomenon of the case can be prevented.

1 is an exploded perspective view
Figure 2 is a front cross-sectional view in the entire bonding state
Figure 3 is a side cross-sectional view of the cabinet before lowering
Figure 4 is a side cross-sectional view of the storage cabinet lowered state
5 is a plan sectional view showing the structure of the power transmission unit;
6 is a schematic side view showing a state of use
Figure 7 is a cross-sectional view of the reinforcing frame is installed on the inner circumferential surface of the case

Hereinafter, specific configurations and effects of the present invention will be described based on the embodiments shown in the drawings.

The lift cabinet according to the present invention includes a case 100, a cabinet 200, and a lift driver 300 as shown in FIGS. 1 to 3.

First, the case 100 serves as a support of the storage cabinet at the same time as the outer casing role of the storage cabinet to be described later as the name, as a whole consists of a rectangular box.

More specifically, the inside and the bottom is formed in the form of a box in which the installation space 110 for accommodating the storage cabinet 200 is formed in the inside and is fixed to the wall or ceiling.

And the guide rail 120 is formed at the middle of the left and right inner surface of the case 100, the guide rail 120 is a stable lifting of the cabinet 200 with a connection function between the case 100 and the cabinet 200 to be described later It is formed to act to induce.

The guide rail 120 is formed in a groove shape of a predetermined depth on the left and right inner surface of the case 100 is made of a straight rail shape having a length corresponding to the moving distance of the storage cabinet.

At this time, the guide rail 120 is inclined downward toward the front end portion from the rear end to form a diagonal line as a whole.

In addition, since the lower portion of the case 100 is in an open state, the bending of the case may occur due to the load generated during the lifting and lowering of the cabinet.

Therefore, as shown in FIG. 7, as the reinforcement frame 101 is formed in the form of an additional reinforcement frame 101 on the inner circumference of the case (), the reinforcement frame 101 is in a state in which both sides of the case and the back plate are simultaneously held. The warpage of the case can be minimized.

For reference, the reinforcement frame 101 may be installed on the outer periphery of the case instead of the inner surface as shown in the drawing, and may be formed on both the inner and outer periphery.

In addition, the reinforcement frame 101 is preferably made of a material having a large bending strength such as metal.

The case 100 further includes a support rail 130 in addition to the guide rail 120.

The support rail 130 is formed to stably support the weight of the stored object including the storage space in the stable mounting and lifting process of the storage space 200. A rail groove 132 having a certain depth as the guide rail 120 is formed And a rail plate 134 is inserted into the rail groove 132.

At this time, the rail groove 132 is formed in the same length and the same angle as the guide rail 120 and is formed on the upper and lower sides based on the guide rail 120, respectively.

In addition, the rail plate 134 serves to prevent case damage due to friction with the support member 350 which will be described later in the process of lifting and lowering the storage function of the practical rail among the support rails 130, and is the same as the rail groove 132. It is made in the shape of a square tube with a length and is made of a material such as metal to minimize wear due to friction.

In addition, the rear side inner wall surface of the case 100 formed up to the rail plate 134 is further formed with a motor installation groove 140 for the installation of the drive motor 310 to be described later.

The cabinet 100 is installed in the case 100 described above.

The cabinet 200 serves as a practical storage function of the stored article, a box shape having a size similar to that of the installation space 110 of the case 100, and an accommodation space 210 of the enclosure is formed therein, and an opening / closing door 220 is provided on the front thereof. ) Is formed.

The cabinet 200 is inserted into the installation space 110 of the case 100, the opening and closing door 220 is exposed to the outside through the front opening of the case 100.

The lifting driving unit 300 is connected to the cabinet 200 and the case 100 installed as described above.

Lifting drive unit 300 generates a driving force necessary for the lifting of the cabinet 200 and at the same time serves as a connection between the cabinet 200 and the case 100, the drive motor 310 and the rotating screw rod 320 and It is configured to include a moving guide member 330.

Among them, the driving motor 310 is a part in which the actual driving force is generated in the elevating driving part 300, and a general rotary motor is used and is installed in the motor installation groove 140 of the case 100.

As the driving motor 310 is inserted into the motor installation groove 140, the space consumed by the driving motor in the installation space 110 of the case 100 is minimized.

These drive motors 310 are installed on both sides of the rear wall surface of the case 100, respectively.

For reference, when the driving motor 310 is connected to a separate control unit 600 and an operation control signal is input through a separate operation button 700, the driving unit 310 drives as the operation signal is transmitted to the driving motor 310. The operation of the motor is controlled.

The rotary screw rod 320 serves to guide the lifting operation of the cabinet by transmitting the driving force of the driving motor 310 to the cabinet 200, and has a rod shape having substantially the same length as the guide rail 120 and the support rail 130. And the circumferential surface is made of a screw groove formed structure.

The rotary screw rod 320 is provided in two, the rear end of each rotary screw rod 320 is connected to the motor shaft of the drive motor 310 is installed in the form drawn out toward the front side.

At this time, each rotating screw rod is positioned in each guide rail 120 in a state inclined at the same angle as the guide rail (120).

The moving guide member 330 constituting the elevating driving unit 300 together with the driving motor 310 and the rotating screw rod 320 has a connection function between the cabinet 200 and the rotating screw rod 320 and the cabinet 200. It serves as a support, it is installed in the form of a rectangular block and protruding from both walls of the cabinet 200.

In this state, each moving guide member 330 is inserted into both guide rails 120 and installed in a state capable of moving along the longitudinal direction of the guide rails 120.

In this state, as the through hole penetrates the front and rear ends, and the rotary screw rods 320 penetrate the through holes, the cabinet 200 eventually moves the moving guide member 330. It has a structure that is connected to the rotating screw rod 320 by a medium.

As the moving guide member 330 is connected to the cabinet 200 and the rotary screw rod 320 while being inserted into the guide rail 120, the weight load of the cabinet 200 is concentrated on the rotary screw rod 320. It is not dispersed in the case 100 through the moving guide member 330 and the guide rail 120.

Therefore, the phenomenon that the rotation of the rotary screw rod is prevented by the weight of the cabinet is prevented, as well as the phenomenon that the connection between the rotary screw rod and the driving motor is broken.

Since the moving guide member 330 and the rotating screw rod 320 are implemented as a general ball screw structure, the moving guide member 330 moves in the longitudinal direction of the rotating screw rod 320 when the rotating screw rod 320 is rotated. Accordingly, it has a structure that moves in both directions linearly, and thus the cabinet 200 also has a structure that moves back and forth in a diagonal direction together.

Thus, the support member 350 is further installed in the cabinet 200 in the state up to the lifting drive unit 300.

The support member 350 serves as an additional support of the storage closet 200 and at the same time serves to induce a stable ascent, and is in the form of a block and protrudes from a point facing the support rail 130 of both sides of the storage closet 200. And is inserted into the rail plate 134 of the support rail 130.

Therefore, the support member 350 also has a structure that is moved along the longitudinal direction of the support rail 130 in the process of moving back and forth in the diagonal direction.

Due to the coupling structure between the support member and the support rail 130, the weight load of the cabinet 200 is transmitted to the case through the support member 350 including the moving guide member 330, so that the cabinet is more stable. Is installed.

For reference, although not shown in the drawings, the mounting positions of the support rail 130 and the support member 350 may be reversed. That is, the support rail 130 is formed on both sides of the cabinet 200, and the support member is a case. It may also be modified into a structure protruding on both inner surfaces of the (100).

In addition, the support member 350 and the support rail 130 may be omitted if only the moving guide member 330 and the guide rail 120 can sufficiently distribute the weight load of the cabinet 200.

Hereinafter, the application of this embodiment by the configuration example and the unique effects generated in the process will be described.

In the state in which the storage cabinet 200 is located in the case 100 as shown in FIG. 3, the load of the storage cabinet 200 and the inside of the storage cabinet 200 acts downward, and the storage cabinet 200 is supported by the moving guide member 330. Since it is installed in a state spanning the case 100 through the member 350, the weight load of the cabinet 200 is not concentrated on the rotating screw rod, but is dispersed through the moving guide member 330 and the support member 350. It is in the state delivered to the case.

Therefore, the phenomenon such as the connection between the rotating screw rod 320 and the drive motor 310 is damaged, as well as the entire cabinet is stably located in the case.

In this state, when the user wants to use the cabinet, when the operation button 700 is pressed, each driving motor 310 is operated at the same time as the operation signal is given from the control unit 600, thereby each rotation screw rod 320 ) Is rotated.

As the rotary screw rod 320 is rotated, both the moving guide members 330 move forward along the longitudinal direction of the rotary screw rod 320, and thus the cabinet 200 also moves linearly forward together.

At this time, as described above, as the rotary screw rod 320 is positioned in an oblique direction, the cabinet 200 is moved forward and descends simultaneously in an oblique direction.

As described above, since the moving guide member 330 is inserted into the guide rail 120, the moving guide member 330 moves along the formation path of the guide rail 120.

Thus, the movement inducing member 330 is inserted into the guide rail 120 and moved in a state in which the load of the cabinet is dispersed in the moving process, so that the stable movement is possible, and the guide rail 120 is rotated or Since it is inclined at the same angle as the sand bar 320, the withdrawal and descending of the cabinet can be made stable.

In addition, since the support member 350 is inserted into the support rail 130 together with the movement inducing member 330, the load of the cabinet 200 is further distributed in the process of moving the cabinet 200 to the front side, thereby stably moving. Not only this is possible, since the support rail 130 is also formed in an oblique direction, it is possible to make the withdrawal and descending of the cabinet 200 more stably.

When the cabinet is sufficiently lowered in the diagonal direction and the moving guide member 330 or the support member 350 is positioned near the end of the guide rail 120 or the support rail 130, the driving motor is stopped to stop the descending of the cabinet. .

When the lowering of the cabinet is completed, the user standing in front of the sink as shown in Fig. 6 raises the arm, as well as opening and closing the door of the cabinet, as well as the operation to remove or receive the storage items in the cabinet can be made smoothly.

In this state, if the operation signal is applied again after the cabinet is used, the cabinet is inserted into the case while the cabinet is raised in a diagonal direction through the opposite process as the driving motor rotates in the opposite direction.

For reference, as shown in FIG. 4, a separate sensor 500 is installed on the moving induction member 330 or the support member 350 to move the induction member 330 or the support member 350 during the lifting and lowering of the cabinet 200. If the driving motor 310 is positioned near the end of each rail may be automatically stopped.

In addition, the sensor 500 may be formed at an end of the support rail 130 or the guide rail 120 instead of the support member 350 or the movement guide member 330.

Thus, the present invention has the advantage that the structure is much simpler than the existing link structure by the lifting drive unit 300 is simply made of a drive motor and a rotating screw rod.

In addition, since the cabinet is simply moved in a straight direction along the longitudinal direction of the rotary screw rod, it can be moved more stably than before, and there is no need to form a collision preventing space between the upper surface of the cabinet 200 and the case. The problem of unnecessarily large size can also be solved.

In addition, since the weight load of the cabinet is distributed through the moving guide member, the guide rail, the support member, and the support rail, the storage cabinet can be stably moved to the weight load, and the phenomenon of the cabinet falling can be prevented.

In addition, the rotary screw rod 320 and the drive motor 310, the moving guide member 330 and the support member 350 are all inserted into the guide rail 120, the support rail 130 and the motor installation groove 140 Therefore, the additional space consumption required for the installation of the above configuration does not occur, thereby eliminating the phenomenon in which the overall size becomes unnecessarily large.

5 is a view showing an example of various modifications of the present invention,

Basically, the basic structure provided with the rotary screw rod 320, the moving guide member 330, and the support member 350 is the same as the above embodiment, while the structure of the lifting drive unit 300 is modified to drive the motor 310. While reducing the number of installations, there is a difference in that the rotational speed and operation timing of both rotating screw rods 320 can be exactly matched at all times.

In more detail, the driving motor 310 is connected to only one of the two rotating screw rods 320, and additionally, the power transmission unit 400 is additionally provided.

At this time, the rear end of the rotary screw rod (hereinafter referred to as the driven screw rod 324) that is not connected to the drive motor is installed in a state rotatably connected to the rear wall of the case.

And the power transmission unit 400 serves to transfer the rotational force of the rotary screw rod (hereinafter referred to as 'drive screw rod 322') connected to the drive motor 310 to the driven screw rod 324 located on the opposite side. ,

A drive rotator 410 in the form of a pulley or sprocket is connected to the rear end of the drive screw rod 322 and a driven rotor of the same type as the drive rotator 410 is connected to the rear end of the driven screw rod 324. The whole 420 is connected and the drive rotary body 410 and the driven rotary body 420 has a structure connected to each other through a connecting body 430, such as a belt or chain.

Due to this structure, the driving screw rod 322 is rotated by the driving motor 310 and the driven screw rod 324 simultaneously rotates through the connecting body 430, and the rotation speed is also the same.

For reference, if a separate drive motor is connected to each rotary screw rod, there may be a difference in operating timing and rotation speed of each rotary screw rod according to the state of each drive motor. Due to the driving force deviation, a phenomenon may occur in which the cabinet 200 is shifted to either side.

However, the drive screw rod 322 and the driven screw rod 324 can be rotated at the same timing and speed at all times provided with the power transmission unit can solve this concern.

Although not shown in the drawing, a door in the form of a hinged door may be installed at the lower part of the case 100 so that the cabinet may be pushed down while the cabinet is lowered, so that the door is automatically opened. Like the reinforcement frame 101 of the above embodiment may serve as a reinforcement of the case.

At this time, the hinge portion of the door may be provided with an elastic member such as a torsion spring shape so that the door can be automatically closed in the process of raising the cabinet.

In addition, the opening and closing door of the cabinet is omitted, and the opening and closing door is installed on the front of the case so that the opening and closing door is pushed forward in the process of descending the cabinet, and the opening and closing door is automatically closed by the elastic member in the process of raising the cabinet. You can also

8 to 11 are views showing another embodiment of the present invention.

Basically, the basic concept of obtaining the elevating driving force by using the rotary screw rod 320 is the same as the above embodiment, but there is a difference in using the transfer wire 800 in transferring the elevating driving force to the cabinet 200.

In more detail, in the present embodiment, as shown in the drawing, the space part 1 is disposed between the rear surface of the cabinet 200 and the rear inner surface of the case 100 in a state where the cabinet 200 is completely accommodated in the case 100. Is formed.

The driving motor 310 is installed in the lower portion of the space portion 1 formed in this way, in which the motor shaft of the driving motor 310 is positioned upward, and the driving motor has a structure capable of forward and reverse rotation.

In addition, the driving motor 310 is electrically connected to an operation switch or other remote control installed in the case, such that the user can control the operation from the outside of the case.

In this state, the rotary screw rod 320 is connected to the motor shaft.

The rotating screw rod 320 is a part for outputting the driving motor 310 for the first time in the same manner as in the above embodiment and is also in the form of a ball screw, It is installed in a connected state.

In this state, the upper end of the rotary screw rod 320 is supported by a separate bearing housing (B), the bearing housing (B) serves to induce a support function and smooth rotation of the rotary screw rod (320), Consists of a bearing embedded in the interior.

The bearing housing (B) is located on the upper side of the surface facing the rear of the cabinet 200 of the case 100, the upper end of the rotary screw rod 320 is positioned in the state fitted to the bearing.

As a result, the rotary screw rod 320 has a structure in which the upper and lower ends are rotated while being connected to the driving motor 310 and the bearing housing, respectively.

In this state, a straight guide rail 920 is installed on the rear side of the case 100.

The straight guide rail 920 serves to guide the vertical movement of the transfer block 910 to be described later when the rotary screw rod 320 rotates, and has a bar shape and a case having the same length as the rotary screw rod 320. The inner surface of the rotating screw rod 320 is positioned in a state facing the horizontal.

 At this time, guide grooves for coupling with the transfer block 910 to be described later are formed along the longitudinal direction at both edges of the straight guide rail 920.

For reference, the linear guide rail 920 may be installed in a form embedded in the case in addition to the structure protruding from the rear of the case, it may be applied to the projection structure instead of the guide groove.

In this state in which the linear guide rail 920 is installed, the rotating screw rod 320 is provided with a transfer block 910.

The transfer block 910 serves to initially transmit the rotational force of the rotary screw rod 320 to the transfer wire 800, which will be described later. It is formed to penetrate up and down.

The transfer block 910 is coupled to the rotating screw rod 320 is passed through the screw hole, the rear of the rail groove (not shown) is formed for sliding coupling with the linear guide rail.

In this state, as the linear guide rail 920 is inserted into the groove of the transfer block, the transfer block 910 is not rotated when the rotary screw rod 320 rotates, and moves straight up and down along the longitudinal direction of the straight guide rail 920. It has a structure that becomes.

Thus, the lifting roller unit is installed on one side of the rotary screw rod 320 in which the transfer block 910 is installed.

The lifting roller unit serves to finally transfer the lifting force of the transfer block 910 to the storage cabinet 200, and is configured to include the support piece 930 and the transfer roller 940.

 Among them, the support piece 930 serves as a support for the fixed installation of the transfer roller 940, which will be described later, is fixedly installed at a point near the side of the rotary screw rod 320 of the rear side of the case.

The support piece 930 can be variously modified as long as it is a structure capable of installing the feed roller 940 such as a simple plate shape, and furthermore, the support piece can be omitted if the feed roller 940 can be directly installed in the case. Do.

The conveying roller 940 serves to transfer the lifting force of the conveying block 910 to the conveying wire 800, which will be described later. It is installed in a state rotatable about an axis.

At this time, the transfer roller 940 is positioned in the state facing the rear midpoint of the cabinet 200, so that the transfer wire 800 to be described later is connected to the midpoint of the rear of the cabinet, the force transmitted through the transfer wire in the lifting process It can be applied uniformly without biasing to either side.

In this state, the transfer roller 940 is connected to the transfer wire 800.

The transfer wire 800 is the final transfer of the lifting force of the transfer block 910 to the storage cabinet () to output the driving force required for substantial lifting induction, the general wire form and the transfer roller in one end connected to the transfer block 910 940 is installed in a wound state.

And in this state, the other end of the transfer wire 800 is connected to the rear of the cabinet 200, wherein the transfer wire 800 is connected to the rear midpoint of the cabinet 200 as described above of the transfer wire 800 Make sure the driving force is not biased on either side of the cabinet.

Accordingly, the transfer wire 800 has a structure in which the storage cabinet () connected thereto is lifted and pulled and released as the center of the transfer roller 940 when the transfer block 910 moves up and down.

For reference, the transfer wire should have sufficient strength such as metal wire so as not to cause breakage even if used for a long time.

Also in this embodiment, the inner side surfaces of the case 100 are formed in an oblique direction inclined downward as the rail grooves 132 toward the front side, and the rail plate 134 is inserted into the rail grooves 132.

In this state, support members 350 protrude from both sides of the cabinet 200, and the support members 350 are inserted into the rail plate 134.

As a result, the cabinet 100 has a structure in which the lifting and lowering is induced in the diagonal direction during the lifting and lowering by the transfer wire 800.

Hereinafter will be described the operation of the present embodiment and the effects generated in the process by this structure.

First, in the state in which the cabinet 200 is fully inserted into the case 100 as shown in FIG. 10, the transfer block is located at the lower end of the rotary screw rod 320 and the transfer wire 800 is completely pulled out, thereby The cabinet 200 is pulled by the pulling force of the transfer wire 800, and the position is fixed.

If you want to lower the cabinet 200 in this state,

When the driving motor 310 is operated, the rotary screw rod 320 is rotated, and thus the transfer block 910 is raised in a straight shape along the longitudinal direction of the rotary screw rod 320 and the linear guide rail.

As the transfer block 910 ascends, the other end of the transfer wire 800 is released based on the transfer roller 940, and thus the cabinet 200 is lowered by its own weight.

At this time, since the conveying wire 800 is always in tension and maintains a proper tension, the cabinet 200 is gradually lowered only by the unwinding length of the conveying wire when descending.

And while the cabinet 200 is lowered in this way, the cabinet 200 is lowered in the cabinet 200 in a diagonal direction because the support member 350 is inserted into the rail plate 134, and gradually moves forward in the descending process. Withdrawn.

On the contrary, when the cabinet 200 is to be raised, the cabinet is lifted through the opposite process and positioned in the case.

As described above, the present embodiment transmits the driving force of the rotary screw rod to the storage cabinet through the transfer roller 940 and the transfer wire 800, and thus, unlike the above embodiment, it is not necessary to install the rotary screw rod in the rail plate. Not only does it need to be installed on both sides of the storage screw rod, it has the advantage of being structurally simple.

FIG. 12 is a view showing a modified structure of the embodiment in which the transfer wire is grafted. The end of the transfer wire 800 is divided into several branches so that each split branch 810 is in the middle including the rear middle point of the cabinet. The difference is that they are connected to both sides at the same time.

As a result, the lifting force by the transfer wire is not only distributed evenly over the rear of the cabinet, but also the load applied to the transfer wire is distributed to each split branch (), which leads to the smooth lifting of the cabinet and the breakage of the transfer wire. It can be prevented.

13 and 14 show yet another modified example,

By providing a separate safety device on the support member 350 and the rail plate 134, it is characterized in that the storage cabinet is prevented from falling down the case when the transfer wire is broken.

As an embodiment of the safety device is applied to this to form a plurality of buried grooves 352 in the bottom surface of the support member 350 in the bottom surface of the support member 350 as shown in the drawing and each buried groove 352 The spring 354 is inserted and installed.

A locking piece 353 is positioned at the end of the spring 354 in the buried groove 352.

In addition, the inner surface near the lower end of the rail plate 134 is formed with a plurality of engaging grooves 135 at intervals along the longitudinal direction.

In this state, in the normal state, when the locking piece 353 is located in the upper section of the point where the locking groove 135 is formed among the rail plates 134, the locking piece 353 is in contact with the rail plate 134 and pressurized. As it is, the spring 354 is compressed to be in a state located in each of the buried grooves 352.

And the locking groove 135 is located below the maximum falling point of the cabinet, that is, the maximum falling point of the support member 350 of the rail plate 134.

By this structure, if the storage wire is broken in the process of descending the storage cabinet 200, the storage cabinet is lowered by its own weight. In this process, when each locking piece 353 is positioned at the position of the locking groove 135, the elastic force of the spring As a result, each engaging piece 353 is drawn out to be fitted into each engaging groove 135.

The cabinet 200 is no longer lowered by the coupling force between the locking piece 353 and the locking groove 135.

Various features of the present invention described above may be implemented by various modifications and combinations by those skilled in the art, but such modifications and combinations are such that the cabinet is elevated in a linear movement form in a diagonal direction along the longitudinal direction of the rotary screw rod when the rotary screw rod is rotated. Therefore, when it is related to the configuration and the purpose to enable a stable ascent and simplify the overall structure as compared to the existing should be determined to fall within the protection scope of the present invention.

100: case 110: installation space
120: guide rail 130: support rail
132: rail groove 134: rail plate
140: motor installation groove 200: cabinet
210: storage space 220: opening and closing door
300: lifting drive 310: drive motor
320: rotating screw rod 330: moving guide member
350: support member 400: power transmission portion
410: driving rotor 420: driven rotor
430: connector 322: drive screw rod
324: driven screw rod 500: sensor
600: control unit 700: operation button

Claims (5)

The case is open at the front and the bottom and has an installation space inside.
A storage cabinet which is accommodated in the installation space so that it can be pulled out and a storage space is formed therein;
A driving motor located at a lower point between a rear surface of the storage space and the case in the installation space;
Rotating screw rod that the lower end is connected to the drive motor and is rotatable,
A moving induction member connected to the rotating screw rod and capable of linearly moving up and down along the longitudinal direction of the rotating screw rod when the rotating screw rod is rotated;
Feed roller is located on one side of the rotating screw rod,
A transfer wire having one end connected to the movement guide member and the other end connected to the storage cabinet in a state spanning the connecting roller;
Elevated storage cabinet comprising a.
In claim 1,
On both side wall surfaces of the case are formed rail grooves inclined downward toward the front side,
A support member fixed to a side wall of the cabinet and connected to the rail groove and movable along the rail groove when the cabinet is elevated;
Elevated storage cabinet further comprising.
3. The method according to claim 1 or 2,
The section from the point spanning the transfer roller to the point connected to the cabinet of the connection wire is divided into a plurality and connected to the cabinet separately.
Lift cabinet.
3. The method of claim 2,
It is located in the horizontal state with the rotating screw rod and the transfer block is connected is a straight guide rail to guide the transfer block in the vertical direction
Elevated storage cabinet further comprising. 3. The method of claim 2,
A plurality of locking grooves formed at the bottom of the lower end of the rail groove;
Buried grooves arranged on the bottom surface of the support member at the same number and spacing as the locking grooves;
A spring formed in each of the buried grooves,
The engaging piece is connected to the end of the spring is located in the buried groove in a state capable of withdrawing to the outside of each buried groove by the elastic force of the spring
Elevated storage cabinet further comprising.

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