CN215819121U - Machine cabinet - Google Patents
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- CN215819121U CN215819121U CN202120861433.1U CN202120861433U CN215819121U CN 215819121 U CN215819121 U CN 215819121U CN 202120861433 U CN202120861433 U CN 202120861433U CN 215819121 U CN215819121 U CN 215819121U
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Abstract
The embodiment of the application provides a cabinet, which comprises at least one displacement assembly and at least one cross beam; the displacement assembly is arranged on the upright post of the cabinet; the cross beam is connected with the stand columns on the two sides of the cabinet through the displacement assembly; the displacement assembly is used for adjusting the position of the cross beam on the cabinet. Because the displacement assembly is arranged on the stand columns at two sides of the cabinet and adjusts the position of the beam on the cabinet, the position of the beam is usually changed around the cabinet, namely the displacement assembly can enable the position of the beam to be changed around the stand columns, therefore, when equipment in the cabinet is required to be maintained, the equipment can be taken out only by adjusting the position of the beam through the displacement assembly so that the beam does not shield the equipment to be maintained, and the equipment is put in after the maintenance of the equipment is completed, so that the beam is not required to be detached and installed, the maintenance efficiency of the equipment is improved, and the quick maintenance of the equipment is realized.
Description
Technical Field
The application relates to the technical field of mechanical equipment, in particular to a cabinet.
Background
The cabinet is a device for storing control equipment such as computers and is a carrier of the control equipment. At present, with the increasing integration density of the cabinet, the weight of the equipment in the cabinet is also increasing. In this case, it is often necessary to increase the strength of the cabinet.
Referring to the structural schematic diagram shown in fig. 1, in order to increase the strength of the cabinet, the existing cabinet is generally configured with a cross beam 10, two sides of the cross beam 10 are respectively fixed with the uprights 20 at two sides of the cabinet, and the cross beam 10 plays a role in increasing the strength of the cabinet.
However, maintenance of the equipment is sometimes required, which requires removal or placement of the equipment in the cabinet. Under the condition, the cross beam needs to be disassembled, the equipment is maintained, and the cross beam is installed after the equipment is placed into the cabinet, so that the operation of equipment maintenance is complicated, and the efficiency of the equipment maintenance is low.
SUMMERY OF THE UTILITY MODEL
In order to solve the problems that the existing cabinet is complex to operate and low in equipment maintenance efficiency when equipment is maintained, the embodiment of the application provides the cabinet.
In a first aspect, an embodiment of the present application discloses a cabinet, including:
at least one displacement assembly and at least one cross beam;
the displacement assembly is arranged on an upright post of the cabinet;
the cross beam is connected with the stand columns on two sides of the cabinet through the displacement assembly;
the displacement assembly is used for adjusting the position of the cross beam on the cabinet.
In the cabinet disclosed in the embodiment of the present application, the displacement assembly can adjust the position of the beam on the cabinet, and therefore, the position of the beam generally changes around the cabinet, that is, the displacement assembly can change the position of the beam around the upright. If need maintain the equipment in the rack, only need through the displacement subassembly, the position of adjustment crossbeam makes the crossbeam no longer shelter from the equipment that needs to maintain, can take out this equipment to after the maintenance of completion equipment, put into this equipment again, thereby need not to dismantle and install the crossbeam.
In an alternative design, the displacement assembly includes:
two rotating arms and two rotating shafts;
the two rotating shafts are respectively embedded into the upright columns on two sides of the cabinet;
the two rotating arms are respectively connected with the upright posts on two sides of the cabinet through the two rotating shafts;
two ends of the beam are respectively connected with the two rotating arms;
the two rotating arms are used for rotating along the two rotating shafts and driving the beam to rotate along the two rotating shafts in the rotating process.
In the rack disclosed in the embodiment of the application, two rotation axes can be followed to two swinging arms rotatory, at rotatory in-process, can drive the crossbeam rotatory along two rotation axes, consequently, the crossbeam can be followed the stand is rotatory from top to bottom, realizes the adjustment of crossbeam position, is convenient for maintain the equipment in the rack.
In an alternative design, the two swivel arms comprise telescopic rods with adjustable length.
In this case, by stretching the rotating arm, the length of the rotating arm can be adjusted, thereby further adjusting the position of the beam.
In an alternative design, the length of the rotating arm is not less than the height of the plugging module in the cabinet.
Through the design, the shielding of the plug-in module by the cross beam can be avoided.
In an alternative design, the displacement assembly includes:
a slider;
the sliding blocks are respectively embedded into the upright columns on the two sides of the cabinet;
the two ends of the cross beam are respectively connected with the sliding blocks;
the sliding block is used for sliding up and down along the upright post and driving the cross beam to slide up and down in the sliding process.
Through the design, when equipment in the cabinet needs to be maintained and the position of the cross beam covers the equipment, so that the equipment cannot be taken out, the cross beam can be translated to other heights by translating the cross beam.
In an alternative design, the displacement assembly further includes:
at least one stop structure;
the stop structure is used for fixing the sliding block.
The stop structure can fix the sliding block, so that the tightness of the connection of the sliding block and the stand column is enhanced.
In an alternative design, the displacement assembly includes:
at least one rotating architecture;
the rotating structure includes: a rotating shaft and a fixed member;
the rotating shaft is arranged on an upright post at one side of the cabinet;
one end of the cross beam is connected with the rotating shaft, and the other end of the cross beam is fixed on the upright post on the other side of the cabinet through the fixing part;
after the fixing member is removed, the cross member is rotated along the rotation axis.
By means of the design, when equipment in the cabinet needs to be maintained, the cross beam can rotate along the rotating shaft after the fixing part is removed,
in an alternative design, the securing element includes: a pin, a screw, or a plug.
In an alternative design, the method further comprises:
a damping washer disposed between the post and the displacement assembly.
The damping washer can reduce the friction force between the displacement assembly and the upright post, and the position of the cabinet can be adjusted conveniently through the displacement assembly.
In an optional design, the cross beam is a cylinder made of stainless steel;
the diameter of the cross beam is not less than 19 mm.
In the cabinet provided by the embodiment of the present application, since the displacement assemblies are disposed on the columns at two sides of the cabinet, and the displacement assemblies adjust the position of the beam on the cabinet, the position of the beam generally changes around the cabinet, that is, the displacement assemblies can change the position of the beam around the columns, for example, the beam can rotate up and down, translate up and down, or rotate back and forth along the columns.
Under this condition, when the equipment in the rack needs to be maintained, the position of the cross beam is adjusted only through the displacement assembly, so that the cross beam does not shield the equipment needing to be maintained, the equipment can be taken out, and the equipment is put in after the maintenance of the equipment is completed, so that the cross beam does not need to be disassembled and installed. Therefore, the cabinet provided by the embodiment of the application can simplify the operation of equipment maintenance and improve the efficiency of equipment maintenance, thereby realizing the rapid maintenance of equipment.
Drawings
Fig. 1 is a schematic structural diagram of a cabinet disclosed in the prior art;
fig. 2 is a schematic structural diagram of a cabinet disclosed in an embodiment of the present application;
fig. 3 is a schematic structural diagram of another cabinet disclosed in the embodiment of the present application;
fig. 4 is a front view of a cabinet disclosed in an embodiment of the present application;
fig. 5 is a schematic structural diagram of another cabinet disclosed in the embodiment of the present application;
fig. 6 is a front view of yet another cabinet disclosed in an embodiment of the present application;
fig. 7 is a schematic structural diagram of another cabinet disclosed in the embodiment of the present application;
fig. 8 is a front view of yet another cabinet disclosed in an embodiment of the present application;
fig. 9 is a schematic structural diagram of another cabinet disclosed in the embodiment of the present application;
fig. 10 is a schematic structural diagram of another cabinet disclosed in the embodiment of the present application.
Detailed Description
The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.
The terminology used in the following examples is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification of this application and the appended claims, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, such as "one or more", unless the context clearly indicates otherwise. It should also be understood that in the following embodiments of the present application, "at least one", "one or more" means one, two or more. The term "and/or" is used to describe an association relationship that associates objects, meaning that three relationships may exist; for example, a and/or B, may represent: a alone, both A and B, and B alone, where A, B may be singular or plural. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.
Reference throughout this specification to "one embodiment" or "some embodiments," or the like, means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the present application. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," or the like, in various places throughout this specification are not necessarily all referring to the same embodiment, but rather "one or more but not all embodiments" unless specifically stated otherwise. The terms "comprising," "including," "having," and variations thereof mean "including, but not limited to," unless expressly specified otherwise.
In order to solve the problems that the existing cabinet is complex to operate and low in equipment maintenance efficiency when equipment is maintained, the embodiment of the application provides the cabinet.
Referring to the schematic structural diagram shown in fig. 2, the cabinet includes: at least one displacement assembly 100 and at least one cross beam 200.
A cabinet often includes a cabinet body and a cabinet door, the cabinet body includes a back panel and a side panel, and two pillars 300 are respectively disposed on two sides of the side panel.
In the present embodiment, the displacement assembly 100 is disposed on a column 300 of the cabinet.
In addition, the cross beam 200 is connected to the pillars on both sides of the cabinet through the displacement assembly 100, that is, the cross beam 200 is horizontally disposed in the cabinet. The cross beam 200 can improve the strength of the cabinet.
The displacement assembly 100 is used to adjust the position of the beam 200 in the cabinet. In the solution provided by the embodiment of the present application, the displacement assembly 100 can drive the displacement of the cross beam to change, and in this case, the position of the cross beam 200 in the cabinet can be changed under the action of the displacement assembly 100.
In the cabinet provided by the embodiment of the application, because the displacement assembly is disposed on the upright of the cabinet, and the displacement assembly adjusts the position of the beam on the cabinet, the position of the beam generally changes around the upright of the cabinet, that is, the displacement assembly can change the position of the beam around the upright, for example, the beam can rotate up and down, translate up and down, or rotate back and forth along the upright.
In the existing cabinet, two ends of a beam are respectively fixed on upright columns at two sides of the cabinet. In this case, when maintenance of the equipment in the cabinet is required, the cross beam is first detached, removed from the cabinet to perform maintenance of the equipment in the cabinet, and then fixed to the cabinet after completion of the maintenance. That is to say, when maintaining the equipment in the existing rack, the crossbeam of installing on the rack needs to be dismantled and installed, leads to the complex operation of equipment maintenance, and equipment maintenance is inefficient.
In the rack that this application embodiment provided, including displacement subassembly and crossbeam, the crossbeam passes through the displacement subassembly is connected with the stand of rack both sides, plays the effect that increases the intensity of rack. In addition, under the drive of the displacement assembly, the position of the beam on the cabinet can be adjusted. Under this condition, when the equipment in the rack needs to be maintained, the position of the cross beam is adjusted only through the displacement assembly, so that the cross beam does not shield the equipment needing to be maintained, the equipment can be taken out, and the equipment is put in after the maintenance of the equipment is completed, so that the cross beam does not need to be disassembled and installed.
Therefore, compared with the existing cabinet, the cabinet provided by the embodiment of the application can simplify the operation of equipment maintenance and improve the efficiency of equipment maintenance, thereby realizing the rapid maintenance of equipment.
In addition, in the cabinet provided by the embodiment of the application, each displacement assembly can be connected with at least one cross beam, so that the number of the displacement assemblies is generally not larger than that of the cross beams. When the number of the devices in the cabinet is large and the weight of the devices is large, more than two displacement assemblies and beams can be arranged to improve the strength of the cabinet.
In the cabinet provided by the embodiment of the application, the displacement assembly can be realized in various forms, and correspondingly, the displacement assemblies in different forms can adjust the position of the cross beam in different ways.
In one possible design, referring to the schematic structural diagram shown in fig. 3, the displacement assembly comprises: two rotating arms 110 and two rotating shafts 120.
The two rotating shafts 120 are respectively embedded into the pillars 300 on both sides of the cabinet, and in addition, the two rotating arms 110 are respectively connected with the pillars 300 on both sides of the cabinet through the two rotating shafts 120. That is, each of the rotating arms 110 is fixed in the column 300 at one side of the cabinet by a rotating shaft 120, in which case the rotating arm 110 can rotate along the rotating shaft 120.
In addition, two ends of the cross beam 200 are respectively connected to the two rotating arms 110. Through the rotating arm 110, the two ends of the beam 200 are respectively connected with the upright posts 300 at the two sides of the cabinet, so that the strength of the cabinet can be enhanced.
The two rotating arms 110 are configured to rotate along the two rotating shafts 120, and in the rotating process, the cross beam 200 is driven to rotate along the two rotating shafts 120. Thus, in this design, the beam 200 can rotate up and down the column. Also, the beam 200 may generally provide hovering in any position during rotation.
A plurality of plug modules are usually disposed in the cabinet, and the devices can be usually placed in slots of the plug modules, that is, the plug modules in the cabinet are used for placing the devices. In the solution provided by the embodiment of the present application, the length of the rotating arm is generally not less than the height of the pluggable module in the cabinet. In this case, the highest position reached by the beam in the rotation process is set as an upper position, and the lowest position reached by the beam is set as a lower position.
To clarify the manner in which the beam 200 moves in position in this design, fig. 4 is disclosed in this application. Fig. 4 is a front view of the cabinet including a shaft 300, and in this design, the beam 200 is rotatable up and down along a rotation shaft 120 connected to the shaft 300. In addition, the arrow direction in fig. 4 indicates the movable direction of the beam 200, and specifically, the arrow indicates that the beam 200 can rotate up and down along the rotation axis 120.
When equipment in the cabinet needs to be maintained and the position of the cross beam covers the equipment, so that the equipment cannot be taken out, the cross beam can be rotated to other positions through rotation of the rotating arm. For example, if the beam is located below and the beam causes an inability to service the equipment, the beam may be rotated to the top to remove the equipment for servicing.
Further, in this design, the two rotating arms may comprise telescopic rods with adjustable lengths. In this case, the length of the rotating arm can be adjusted by stretching the rotating arm, thereby further adjusting the position of the beam.
In addition, if the length of the rotating arm is adjustable, in the present embodiment, the length of the rotating arm generally refers to the maximum length that can be achieved by the rotating arm. That is, if the two rotating arms include telescopic rods with adjustable lengths, the maximum length of the rotating arms can be achieved is usually not less than the height of the plugging module in the cabinet.
In the design, the beam rotates under the driving of the rotating arm, so that the position of the beam can be adjusted, the beam does not need to be detached when equipment in the cabinet needs to be maintained, and in the rotating process, the beam can provide tension for the cabinet so as to enhance the strength of the cabinet.
In addition, in the solution provided by the embodiments of the present application, one or more displacement assemblies may be provided in general. If more than two displacement assemblies are arranged, the beams connected with other displacement assemblies can provide tension for the cabinet in the rotating process of the beam connected with one displacement assembly, so that the strength of the cabinet is further enhanced.
Generally, the higher the strength requirement of the cabinet, the greater the number of displacement assemblies arranged in the cabinet and the number of beams connected with the columns of the cabinet through the displacement assemblies.
Wherein, if two displacement assemblies provided by the embodiment of the present application are disposed in the cabinet, the two displacement assemblies can be referred to as a double-rotating-arm structure.
In the prior art, in the process of maintaining equipment, the cross beam is often required to be detached, and after the equipment is maintained, the detached cross beam is installed again, so that the steps are complicated.
In the cabinet provided by the embodiment of the application, in the process of equipment maintenance, the position of the beam can be adjusted only by rotating the beam without dismounting the beam, and correspondingly, the beam is not required to be mounted after dismounting. Therefore, compared with the existing cabinet, the cabinet provided by the embodiment of the application can simplify the steps of equipment maintenance, improve the efficiency of equipment maintenance and realize the rapid maintenance of equipment.
Furthermore, when the existing cabinet is used for maintaining equipment, the cross beam needs to be detached. In order to ensure the strength of the cabinet after the cross beam is detached, the cross beam is required to be arranged at other positions in the cabinet. That is, in the conventional cabinet, two or more beams must be arranged.
And in the scheme that this application embodiment provided, the crossbeam need not to demolish to, the crossbeam is at rotatory in-process, also can provide the tension for the rack, plays the effect that strengthens rack intensity, consequently, compares with current rack, and the crossbeam quantity of installation in the rack that this application embodiment provided is less.
For example, in the existing cabinet, at least two beams need to be installed, and after one beam is disassembled, the rest beams play a role in increasing the strength of the cabinet. In the cabinet provided by the embodiment of the application, only one beam can be installed, and the beam can provide tension in the rotating process, so that the effect of increasing the strength of the cabinet is achieved. Therefore, in the cabinet provided by the embodiment of the application, a smaller number of cross beams can be installed.
And equipment can also be placed in the area where the cross beams are installed, and because the cabinet provided by the embodiment of the application can be provided with a small number of cross beams, compared with the existing cabinet, the cabinet provided by the embodiment of the application can be used for placing a large number of equipment, and the arrangement density of the equipment is improved.
In another possible design, referring to the schematic structural diagram shown in fig. 5, the displacement assembly includes: a slider 130.
The sliding block 130 in one displacement assembly generally includes two. The sliding blocks 130 are respectively embedded into the posts 300 on both sides of the cabinet.
In the solution provided by the embodiment of the present application, grooves may be provided on the uprights 300 on both sides of the cabinet, and the sliding block 130 is embedded into the grooves, so as to embed the sliding block 130 into the uprights 300.
In addition, both ends of the cross beam 200 are respectively connected with the sliding blocks, that is, one end of the cross beam 200 is connected with the sliding block 130 on one side of the upright, and the other end of the cross beam 200 is connected with the sliding block 130 on the other side. In this case, the cross beam 200 is connected to the upright 300 of the cabinet through the sliding block 130, so that the strength of the cabinet can be enhanced.
The sliding block 130 is used for sliding up and down along the upright column and driving the cross beam to slide up and down in the sliding process. Thus, in this design, the beam 200 can translate up and down the column.
To clarify the manner in which the beam 200 is shifted in position in this design, fig. 6 is disclosed in this embodiment of the application. Fig. 6 is a front view of a cabinet that includes a post 300 and, in this design, the beam 200 can translate up and down the post under the influence of a sliding block. In addition, the arrow in fig. 6 indicates the movable direction of the beam 200, and in particular, the arrow indicates that the beam 200 can move up and down along the upright 300.
When equipment in the cabinet needs to be maintained and the position of the cross beam covers the equipment, so that the equipment cannot be taken out, the cross beam can be translated to other heights by translating the cross beam. For example, if the beam is located higher up in the cabinet and the beam causes an inability to service the equipment, the beam may be pulled downward to move the beam downward to facilitate removal of the equipment for maintenance.
In the rack that this application embodiment provided, in the equipment maintenance process, only need through the sliding block, along this crossbeam of stand translation, can realize the adjustment of crossbeam position, need not to dismantle the crossbeam, corresponding, also need not to install this crossbeam again after dismantling. Therefore, compared with the existing cabinet, the cabinet provided by the embodiment of the application can simplify the steps of equipment maintenance, improve the efficiency of equipment maintenance and realize the rapid maintenance of equipment.
Further, in this design, the displacement assembly further comprises: at least one stop structure. The stop structure is used for fixing the sliding block.
The stop structure may be implemented in various forms, and for example, the stop structure may be at least one of a pin, a screw, and a bolt.
In the scheme that this application embodiment provided, the sliding block is embedded into in the stand of rack both sides. In addition, in order to strengthen the tightness of the connection between the sliding block and the upright post, the sliding block can be fixed through a stop structure. If the position of the cross beam needs to be adjusted, the sliding block can be translated after the stop structure is removed. In addition, after the sliding block is translated to a proper position, the translated sliding block can be fixed through the stop structure.
For example, if the stop structure is a pin or a pin, the pin or pin can be pulled out and then the slider can be translated. Alternatively, if the stop structure is a screw, the screw can be removed and the slider can be translated.
Although the scheme provided by the embodiment of the application increases the operation of removing the stop structure in the process of equipment maintenance, in the design, the cross beam does not need to be removed. In existing cabinets, however, the cross-beams are usually fixed to the uprights, in which case it is necessary to remove not only the parts for fixing the cross-beams, but also the cross-beams. Therefore, compared with the existing cabinet, the cabinet provided by the embodiment of the application reduces the operation of removing the cross beam, and is more simplified.
The cross beam connected with the sliding block in one displacement assembly comprises at least one cross beam. Wherein, if the rack is higher to the requirement of intensity, in the rack that this application embodiment provided, the crossbeam that is connected with the sliding block in the displacement subassembly can set up many, and many crossbeams are located gliding not co-altitude.
Further, in the scheme provided by the embodiment of the application, the cross beam does not need to be detached, and only needs to be translated up and down when equipment in the cabinet needs to be maintained. And the crossbeam also can provide the tension for the rack at the in-process of translation from top to bottom, plays the effect of reinforcing rack intensity, consequently, compares with current rack, and the crossbeam quantity of installation is less in the rack that this application embodiment provided, and more quantity's equipment can be placed to this rack, has improved the deployment density of equipment.
In another possible design, referring to the schematic structural diagram shown in fig. 7, the displacement assembly includes: at least one rotating architecture.
Wherein the rotating structure includes: a rotating shaft 140 and a fixing member 150.
The rotating shaft 140 is disposed on the pillar 300 at one side of the cabinet, and in addition, one end of the beam 200 is connected to the rotating shaft 140, and the other end of the beam 200 is fixed to the pillar at the other side of the cabinet by the fixing member 150.
After the fixing member 150 is removed, the cross beam rotates along the rotation shaft 140.
In this design, a rotating structure is provided, which includes a rotating shaft 140 and a fixing member 150, the rotating shaft 140 and the fixing member 150 are applied to the columns on different sides, and the fixing member 150 is detachable from the columns. In this case, one end of the cross member 200 is connected to the rotation shaft 140, and the other end thereof may be fixed to a pillar at the other end by the fixing member 150.
When the cross beam 200 is fixed on the posts by the fixing part 150, two ends of the cross beam 200 are respectively connected with the posts on two sides of the cabinet, in this case, the cross beam 200 can increase the strength of the cabinet.
In addition, if the cross member 200 makes it impossible to maintain the equipment, the fixing member 150 may be removed from the column. After the fixing member 150 is removed, the cross member 200 may be rotated along the rotation shaft 140, so that the maintenance of the equipment may be performed.
To clarify the manner in which the beam 200 is shifted in position in this design, fig. 8 is disclosed in this embodiment of the application. Fig. 8 is a front view of a cabinet including a post 300, and in this design, one end of a beam 200 is connected to a rotating shaft 140 in a rotating structure, and the other end of the beam 200 is fixed to a post 330 on the other side of the cabinet by a fixing member 150. In addition, the arrow direction in fig. 8 indicates the direction in which the beam 200 can move, and in particular, the arrow direction in fig. 8 indicates that the beam 200 can rotate along the rotation axis 140.
After the fixing part 150 is removed, the cross beam 200 can rotate along the rotation axis, and the larger the rotation angle of the cross beam 200 is, the smaller the shielding area of the cabinet is generally caused. And, after the beam 200 is rotated, maintenance of the equipment can be achieved.
In the scheme provided by the embodiment of the application, when equipment needs to be maintained, only the fixing part needs to be removed, and compared with the existing cabinet, the cabinet provided by the embodiment of the application can simplify the steps of equipment maintenance, improve the efficiency of equipment maintenance and realize the quick maintenance of the equipment.
In addition, in the cabinet provided by the embodiment of the application, after the fixing part for fixing a certain cross beam is removed, the cross beam does not provide tension for the cabinet any more, and the effect of enhancing the strength of the cabinet cannot be achieved. Therefore, in the embodiment of the present application, a plurality of displacement assemblies may be provided, or one displacement assembly may include more than two rotating structures, in which case, when the fixing part in one of the rotating structures is removed, the other rotating structures may fix the cross beam on the upright, so that the other fixed cross beam provides a tension force for the cabinet, so as to improve the strength of the cabinet.
Further, in the solution provided by the embodiments of the present application, the fixing component may be implemented in various forms. Illustratively, the fixing member includes: a pin, a screw, or a plug. Of course, the fixing component may also be other components that can be used for the cross beam, and the embodiment of the present application is not limited thereto.
Further, referring to the schematic structural diagram shown in fig. 9, in the cabinet provided in the embodiment of the present application, the cabinet further includes: a dampening washer 400 disposed between said mast 300 and said displacement assembly 100. In fig. 9, the displacement assembly 100 includes a rotating structure including a rotating shaft, and the damping washer 400 is located between the shaft 300 and the rotating shaft, but in a practical application scenario, the displacement assembly 100 may also be another form of displacement assembly provided in the embodiment of the present application, and the embodiment of the present application is not limited thereto.
The damping washer 400 may reduce friction between the displacement assembly and the pillar, thereby facilitating adjustment of the position of the cabinet by the displacement assembly.
Wherein if the displacement assembly comprises a rotating arm and a rotating shaft, the damping washer may be disposed between the rotating shaft and the column; if the displacement assembly comprises a sliding block, the damping washer may be disposed between the sliding block and the column; if the displacement assembly includes a rotating shaft and a stationary member, the damping washer may be disposed between the rotating shaft and the post.
In addition, in the solution provided in the embodiment of the present application, a damping washer may be further disposed at another position of the cabinet, for example, a damping washer may be disposed between the rotating arm and the rotating shaft, so as to reduce a friction force when the rotating arm rotates along the rotating shaft.
In order to clarify the framework of the cabinet provided in the embodiment of the present application, fig. 10 is further provided in the embodiment of the present application, and fig. 10 is another exemplary diagram provided in the embodiment of the present application. In fig. 10, a cross beam 200, a column 300, and a damping washer 400 disposed between the column 300 and a displacement assembly are included, wherein the displacement assembly includes a rotating structure including the rotating shaft 140 and a fixing part (the fixing part is not shown in fig. 10) in fig. 10, and the rotating shaft 140 is connected to the column 300 by a connection member 141, and the connection member 141 may be a rivet pin or the like.
In the embodiment of the present application, the cross beam is used to reinforce the strength of the cabinet, and therefore, the diameter and material of the cross beam need to be selected to satisfy sufficient rigidity and strength so as to provide sufficient tension for the cabinet and avoid deformation of the cabinet due to large pressure.
In a possible design, in the cabinet provided by the embodiment of the present application, the cross beam is a cylinder made of stainless steel, and the diameter of the cross beam is not less than 19 mm. With this design, the cross beam is generally able to provide sufficient strength to the cabinet.
Of course, the cross beam can be made of other materials with stronger strength besides stainless steel materials. In addition, the beam may have other shapes than a cylinder. For example, the beam may be a rectangular parallelepiped or other polygonal body.
In addition, in the case where the beam is a cylinder, the beam needs to have a sufficient diameter so as to be able to provide sufficient strength. Wherein the diameter of the beam is typically 19 mm, or other values greater than 19 mm.
Although the embodiments of the present invention have been described with reference to the accompanying drawings, the scope of the present invention is not limited thereto, and various modifications and variations which do not require inventive efforts and which are made by those skilled in the art are within the scope of the present invention.
The above-described embodiments of the present invention should not be construed as limiting the scope of the present invention.
Claims (10)
1. A cabinet, comprising:
at least one displacement assembly and at least one cross beam;
the displacement assembly is arranged on an upright post of the cabinet;
the cross beam is connected with the stand columns on two sides of the cabinet through the displacement assembly;
the displacement assembly is used for adjusting the position of the cross beam on the cabinet.
2. The cabinet of claim 1, wherein the displacement assembly comprises:
two rotating arms and two rotating shafts;
the two rotating shafts are respectively embedded into the upright columns on two sides of the cabinet;
the two rotating arms are respectively connected with the upright posts on two sides of the cabinet through the two rotating shafts;
two ends of the beam are respectively connected with the two rotating arms;
the two rotating arms are used for rotating along the two rotating shafts and driving the beam to rotate along the two rotating shafts in the rotating process.
3. The cabinet of claim 2,
the two rotating arms comprise telescopic rods with adjustable lengths.
4. The cabinet of claim 2,
the length of the rotating arm is not less than the height of the plugging module in the cabinet.
5. The cabinet of claim 1, wherein the displacement assembly comprises:
a slider;
the sliding blocks are respectively embedded into the upright columns on the two sides of the cabinet;
the two ends of the cross beam are respectively connected with the sliding blocks;
the sliding block is used for sliding up and down along the upright post and driving the cross beam to slide up and down in the sliding process.
6. The cabinet of claim 5, wherein the displacement assembly further comprises:
at least one stop structure;
the stop structure is used for fixing the sliding block.
7. The cabinet of claim 1, wherein the displacement assembly comprises:
at least one rotating architecture;
the rotating structure includes: a rotating shaft and a fixed member;
the rotating shaft is arranged on an upright post at one side of the cabinet;
one end of the cross beam is connected with the rotating shaft, and the other end of the cross beam is fixed on the upright post on the other side of the cabinet through the fixing part;
after the fixing member is removed, the cross member is rotated along the rotation axis.
8. The cabinet of claim 7,
the fixing member includes: a pin, a screw, or a plug.
9. The cabinet of any one of claims 1 to 8, further comprising:
a damping washer disposed between the post and the displacement assembly.
10. The cabinet of any one of claims 1 to 8,
the cross beam is a cylinder made of stainless steel;
the diameter of the cross beam is not less than 19 mm.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202120861433.1U CN215819121U (en) | 2021-04-25 | 2021-04-25 | Machine cabinet |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202120861433.1U CN215819121U (en) | 2021-04-25 | 2021-04-25 | Machine cabinet |
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