CN111801000B - Real machine cloud measurement cabinet - Google Patents

Abstract

The utility model provides a real machine cloud measurement cabinet, which comprises at least one signal shielding cabinet body, wherein a rotatable base is arranged in the signal shielding cabinet body; the rotatable base is provided with an equipment supporting frame for supporting the test equipment and communication equipment for communicating the test equipment with the outside; the test equipment is arranged on one side of the equipment support frame, and the communication equipment is positioned on the other side of the equipment support frame; the rotatable base is used for rotating the test equipment or the communication equipment to the preset opening position of the signal shielding cabinet body. This openly utilizes rotatable base, and the test equipment that will survey or the communication equipment that will need the maintenance to change in the test process rotates to same preset opening position department, has realized utilizing same opening to realize functional test and equipment maintenance simultaneously, has improved the signal shielding effect between the different signal shielding cabinet bodies in this real quick-witted cloud survey rack to area is little.

Description

Real machine cloud measurement cabinet

Technical Field

The utility model relates to an automation and test technical field particularly, relate to a cabinet is surveyed to real quick-witted cloud.

Background

The real machine cloud test is to test functions of applications and the like by using a large amount of testing equipment such as mobile phones and flat panels to ensure the use quality of the applications and the like. In real machine cloud measurement, a large amount of test equipment is used, so that the test equipment needs to be placed in different shielding cabinets, and signals are isolated among the different shielding cabinets.

At present, in order to maintain and replace hardware facilities such as communication equipment and network cables, a back door is generally arranged on a shielding cabinet body, and the signal shielding effect between different cabinet bodies is influenced. And the cabinet for real machine cloud measurement adopts a large box body design, so that workers can directly enter the box body to maintain or replace hardware facilities. The cabinet occupies a large area, is high in cost, and has a large opening to influence the signal shielding effect.

Disclosure of Invention

In view of the above, the present disclosure at least provides a real machine cloud testing cabinet.

The utility model provides a real-machine cloud measurement cabinet, which comprises at least one signal shielding cabinet body, wherein a rotatable base is arranged in the signal shielding cabinet body; the rotatable base is provided with an equipment supporting frame for supporting test equipment and communication equipment for communicating the test equipment with the outside;

the test equipment is arranged on one side of the equipment support frame, and the communication equipment is positioned on the other side of the equipment support frame;

the rotatable base is used for rotating the test equipment or the communication equipment to a preset opening position of the signal shielding cabinet body.

In one possible embodiment, the signal shielding cabinet further comprises a rotatable supporting frame connected with the rotatable base;

the rotatable support frame is used for driving the rotatable base to rotate.

In one possible embodiment, the signal shielding cabinet further comprises a power line, a network cable, a filter and a power supply device; the power supply equipment is arranged on the rotatable base and is positioned on the same side of the equipment support frame as the communication equipment;

the power line and the network cable penetrate through the rotatable support frame, one end of the power line is connected with the power supply equipment, and the other end of the power line is connected with the filter; one end of the network cable is connected with the communication equipment, and the other end of the network cable is connected with external network equipment;

an opening is formed in the rotatable supporting frame and used for replacing the power line or the network cable.

In a possible embodiment, at least one supporting part for supporting the test equipment, at least one wire arranging device and at least one wire collecting device are arranged on the equipment supporting frame; the supporting part and the test equipment are positioned on the same side of the equipment supporting frame, and the wire arranging device and the wire concentrator are positioned on the other side of the equipment supporting frame;

the supporting part is provided with a plurality of equipment supporting seats, and each equipment supporting seat is used for supporting one piece of test equipment;

each supporting seat is provided with a communication connecting line connected with the test equipment; the communication connecting line is connected with the concentrator through the wire arranging device.

In one possible embodiment, the rotatable base is quadrilateral; the support portion is parallel to the longest diagonal line of the quadrangle.

In one possible embodiment, the equipment support base is a groove type support base, and comprises two side walls forming a groove and a bottom plate; both of the two side walls are movably connected to the bottom plate;

the communication connecting line is arranged in the groove of the equipment supporting seat.

In a possible embodiment, the equipment support frame is further provided with at least one processor, at least one hub data line, at least one processor power line, at least one hub power line, and a processor communication line; the processor, the hub data line, the processor power line, the hub power line and the processor communication line are located on the same side of the equipment support frame as the hub;

the processor is connected with the hub through the hub data line; the processor power line is connected with the processor and the power supply device; the hub power line is connected with the hub and the power supply equipment; the processor communication line is connected with the processor and the communication device.

In a possible implementation manner, at least one supporting beam is further arranged on the equipment supporting frame, and the supporting beam and the supporting part are respectively located at positions corresponding to two sides of the equipment supporting frame;

the processor and the hub are arranged on the supporting beam.

In one possible embodiment, the support portion comprises a support floor and a support baffle; the equipment supporting seat is arranged on the supporting bottom plate, and the supporting baffle is arranged on the upper side of the supporting floor and used for preventing the test equipment from toppling.

In a possible embodiment, the real-aircraft cloud measurement cabinet further includes at least one temperature adjusting device and at least one temperature monitoring device;

the temperature adjusting device is arranged on the outer side wall of the signal shielding cabinet body, the temperature monitoring device is arranged inside the signal shielding cabinet body, and the temperature adjusting device is connected with the temperature monitoring device;

the temperature monitoring equipment is used for detecting the temperature in the signal shielding cabinet body, generating a control command based on the detected temperature and sending the control command to the temperature adjusting equipment, so that the temperature adjusting equipment adjusts the temperature in the signal shielding cabinet body based on the control command.

The utility model provides a real machine cloud measurement cabinet, which comprises at least one signal shielding cabinet body, wherein a rotatable base is arranged in the signal shielding cabinet body; the rotatable base is provided with an equipment supporting frame for supporting the test equipment and communication equipment for communicating the test equipment with the outside; the test equipment is arranged on one side of the equipment support frame, and the communication equipment is positioned on the other side of the equipment support frame; the rotatable base is used for rotating the test equipment or the communication equipment to the preset opening position of the signal shielding cabinet body. This openly utilizes rotatable base, and the test equipment that will observe or the communication equipment that will need the maintenance to change in the test procedure rotates to same preset opening position department, has realized utilizing same opening to realize functional test and equipment maintenance simultaneously, has improved the signal shielding effect between the different signal shielding cabinet bodies in this real quick-witted cloud survey rack to area is little.

Drawings

To more clearly illustrate the technical solutions of the embodiments of the present disclosure, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present disclosure and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings may be obtained from the drawings without inventive effort.

Fig. 1 shows a schematic structural diagram of a real-aircraft cloud testing cabinet provided by an embodiment of the present disclosure;

fig. 2 shows a schematic diagram of another real-aircraft cloud testing cabinet provided by an embodiment of the present disclosure accessing an external power supply and an external data network;

fig. 3 is a schematic structural diagram illustrating a groove type supporting seat in a real-machine cloud testing cabinet according to an embodiment of the present disclosure;

fig. 4 is a schematic diagram illustrating that another real-machine cloud testing cabinet provided by an embodiment of the present disclosure is connected to an external power supply;

fig. 5 shows a schematic structural diagram of another real-machine cloud testing cabinet provided by an embodiment of the present disclosure;

fig. 6 shows a schematic structural diagram of another real machine cloud measurement cabinet provided in an embodiment of the present disclosure;

fig. 7 shows a schematic diagram of a layer corresponding to a hub in a real-machine cloud testing cabinet according to another embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present disclosure more clear, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the drawings in the embodiments of the present disclosure, and it should be understood that the drawings in the present disclosure are for illustrative and descriptive purposes only and are not used to limit the scope of the present disclosure. Additionally, it should be understood that the schematic drawings are not necessarily drawn to scale. The flowcharts used in this disclosure illustrate operations implemented according to some embodiments of the present disclosure. It should be understood that the operations of the flow diagrams may be performed out of order, and steps without logical context may be performed in reverse order or simultaneously. In addition, one skilled in the art, under the direction of the present disclosure, may add one or more other operations to the flowchart, and may remove one or more operations from the flowchart.

In addition, the described embodiments are only a few embodiments of the present disclosure, not all embodiments. The components of the embodiments of the present disclosure, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present disclosure, presented in the figures, is not intended to limit the scope of the claimed disclosure, but is merely representative of selected embodiments of the disclosure. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the disclosure without making creative efforts, shall fall within the protection scope of the disclosure.

It should be noted that the term "comprising" is used in the embodiments of the present disclosure to indicate the presence of the features stated hereinafter, but does not exclude the addition of further features.

The utility model provides a rack is surveyed to real quick-witted cloud, but this rack is surveyed to real quick-witted cloud utilizes rotating base, and the test equipment that will survey in the test procedure or the communication equipment that will need the maintenance to be changed rotate to same preset opening position department, has realized utilizing same opening to realize functional test and equipment maintenance simultaneously, has improved the signal shielding effect between the different signal shielding cabinet bodies in this rack is surveyed to real quick-witted cloud to area is little.

The real-machine cloud testing cabinet disclosed by the invention is explained by specific embodiments.

The embodiment of the present disclosure provides a real-machine cloud measurement cabinet, as shown in fig. 1, including at least one signal shielding cabinet body 100, a rotatable base 101 is disposed in the signal shielding cabinet body 100; the rotatable base 101 is provided with a device support frame 103 for supporting the testing device 102 and a communication device 104 for communicating the testing device 102 with the outside. The test device 102 is disposed on one side of the device support frame 103, and the communication device 104 is disposed on the other side of the device support frame 103. The rotatable base 101 is used for rotating the testing device 102 or the communication device 104 to a preset opening position of the signal shielding cabinet 100.

The signal shielding cabinet 100 can shield signals outside the signal shielding cabinet 100, and the test equipment 102 in the signal shielding cabinet 100 cannot receive signals outside the signal shielding cabinet 100.

The communication device 104 may include a switch and a WIFI access APP device.

It should be noted that other hardware facilities required for real machine cloud measurement, such as the power supply device 105, the wire organizer 106, the hub 107, etc., may also be disposed in the signal shielding cabinet 100 on the same side as the communication device 104. When the hardware facilities need to be replaced or repaired, the hardware facilities only need to be rotated to the preset opening position by using the rotatable base 101.

By utilizing the rotatable base 101, the test equipment 102 needing to be observed in the test process or the hardware facilities needing to be maintained and replaced are rotated to the same preset opening position, so that the functional test and the equipment maintenance are simultaneously realized by utilizing the same opening, the signal shielding effect among different signal shielding cabinet bodies in the real machine cloud testing cabinet is improved, and the occupied area is small.

As shown in fig. 1, in order to drive the rotatable base 101 to rotate, a rotatable supporting frame 108 connected to the rotatable base 101 may be further disposed in the signal shielding cabinet 100. With the rotation of the rotatable supporting frame 108, the rotatable base 101 is driven to rotate, so as to rotate the test equipment 102 to be observed in the test process or the hardware facilities to be repaired and replaced to the preset opening position.

In order to implement a real-machine cloud test, an external power supply and an external data network need to be introduced from the outside, so a power line 109 and a network cable 110 may be disposed in the signal shielding cabinet 100, the power line 109 is used for accessing an external power supply, and the network cable 110 is used for accessing an external data network. In order to shield electromagnetic signals outside the signal shielding cabinet 100, a filter 111 is arranged in the signal shielding cabinet 100, an external power supply needs to be connected to the filter 111 before the power line 109 introduces the external power supply, and then current output by the filter is input into the signal shielding cabinet 100 through the power line 109.

In order to achieve the signal shielding effect, the network cable 110 may use a dedicated shielding pump network cable, or an optical fiber is connected to the network cable 110 after being subjected to photoelectric conversion.

As shown in fig. 2, an external power source and an external data network may be accessed from an input port 117 at the bottom side of the signal shielded cabinet 100.

In order to supply power to hardware facilities, such as the communication device 104, the hub 107, and the like, in the signal shielding cabinet 100, a power supply device 105 is further provided in the signal shielding cabinet 100. As shown in fig. 1, the power supply line 109 is connected to the power supply apparatus 105 after an external power source is introduced. In particular implementations, the power supply device 105 may be a power strip.

As shown in fig. 1, the power supply device 105 is disposed on the rotatable base 101 and is located on the same side of the device support 103 as the communication device 104.

In a specific implementation, as shown in fig. 1, the power line 109 and the network cable 110 pass through the rotatable supporting frame 108, one end of the power line 109 is connected to the power supply device 105, the other end of the power line 109 is connected to the filter 111, and the filter 111 is connected to an external power source; one end of the network cable 110 is connected to the communication device 104, and the other end of the network cable 110 is connected to an external network device, i.e., an external data network.

The rotatable support frame 108 is provided with an opening, that is, the rotatable support frame 108 is a non-closed structure, and is used for replacing the power line 109 or the network cable 110.

As shown in fig. 4, the external power supply may be directly connected to the power supply line 109, and may be processed by the filter 111 before being connected to the power supply apparatus 105.

As shown in fig. 1, at least one support part 112 may be provided at one side of the device support stand 103 in order to support and fix the test device 102. In order to arrange the communication connection lines 113 used by each test device 102 in the signal shielding cabinet 100, at least one wire arranging device 106 is provided on the device support frame 103 at a position corresponding to the support portion 112. Wherein the supporting part 112 and the wire organizer 106 are respectively arranged at both sides of the equipment supporting frame 103. The number of wire organizers 106 is determined according to the number of test devices 102 supported by the support 112.

At least one hub 107 is provided at a position corresponding to the support portion 112, and the communication connection line 113 is connected to the hub 107 after passing through the wire organizer 106. The hub 107 and the organizer 106 are located on the same side of the equipment support rack 103.

The support portion 112 is used to support the test equipment 102, so that the support portion 112 is located on the same side of the equipment support stand as the test equipment 102.

As shown in fig. 1, a plurality of device holders 116 are disposed on the supporting portion 112, and each device holder 116 is used for supporting one testing device 102. Each support seat 116 is provided with a communication connection line 113 connected with the test equipment 102.

As shown in fig. 3, the device holder 116 may be designed as a recessed holder for more securely supporting the test device, and may specifically include two sidewalls 118 and a bottom plate 119 forming the recess. To accommodate different sized test devices, both side walls 118 are removably attached to the base 119. The communication connection 113 may be disposed in a recess of the equipment support stand 116. In use, the bottom of the test apparatus is attached to the base plate 119 and the sides are attached to the two side walls 118.

As shown in fig. 1, the rotatable base 101 may be provided in a quadrangular shape. In order to support more test devices 102, to maximize the utilization of signal shielding of the space within the cabinet 100, and to maximize the minimum degree of rotation of the rotatable base 101 during maintenance of the hardware, the support 112 may be disposed parallel to the longest diagonal of the quadrilateral.

Of course, the rotatable base 101 may be provided in other shapes, such as triangular. The support portion 112 may have other orientations, as shown in fig. 5, for example, the support portion 112 is perpendicular to the two side edges of the equipment support frame 103.

As shown in fig. 6, at least one processor 120 is further disposed on the equipment support rack 103, the processor 120 may be disposed at a position corresponding to the support portion 112, and the processor 120 and the support portion are respectively located at both sides of the equipment support rack 103. The processor 120 may be a mini personal computer PC.

As shown in fig. 6, in a specific implementation, a plurality of layers may be disposed on the device support frame 103, where each layer includes one processor 120, one hub 107, and at least one wire organizer 106, and the number of the wire organizers 106 is determined according to the number of the test devices 102 connected to the hub. A supporting part 112 for supporting the testing device 102 is arranged at a position corresponding to the other side of the device supporting frame 103 far away from the processor 120.

The communication connection 113 connected to the test equipment 102 is connected to the hub 107 through the wire organizer 106, the hub 107 is connected to the processor 120, and the processor 120 is connected to the communication equipment 104.

As shown in fig. 6, each layer is further provided with a hub data line 121, a processor power line 122, a hub power line 123, and a processor communication line 124. The processor 120, the hub data line 121, the processor power line 122, the hub power line 123, and the processor communication line 124 are located on the same side of the device support shelf 103 as the hub 107.

The processor 120 is connected with the hub 107 through the hub data line 121; the processor power line 122 is connected with the processor 120 and the power supply apparatus 105; the hub power line 123 is connected to the hub 107 and the power supply apparatus 105; the processor communication line 124 is coupled to the processor 120 and the communication device 104.

In order to support the hub 107 and the processor 120 on each floor, a support beam may be provided on a side of the equipment support frame 103 away from each support portion 112, the support beam and the support portion 112 being located at corresponding positions on both sides of the rack; the processor 120 and the hub 107 are arranged on the supporting beam.

In particular implementations, as shown in fig. 6, the processor power line 122 and the hub power line 123 on each level may be connected to the power sourcing equipment 105 through the data bucket column 125, and the processor communication line 124 on each level may be connected to the communication equipment 104 through the data bucket column 125.

As shown in fig. 7, the processor power lines 122, the hub power lines 123 and the processor communication lines 124 on all levels are connected to the processors 120 and the hub 107 on each level through the data bucket posts 125. Each layer connects the hub 107 and the processor 120 via a hub data line 121. One outlet 126 is provided on each layer.

As shown in fig. 1, the support part 112 may include a support bottom plate 1121 and a support baffle 1122; the equipment supporting base 116 is disposed on the supporting bottom plate 1121, and the supporting baffle 1122 is disposed on the upper side of the supporting floor 1121 for preventing the test equipment from toppling.

In order to control the temperature in the signal shielding cabinet body, the real-machine cloud measurement cabinet further comprises at least one temperature adjusting device and at least one temperature monitoring device. Wherein, the quantity of temperature regulation equipment and the quantity of temperature monitoring equipment all equals with the quantity of signal shielding cabinet body. A temperature regulating device is arranged on the outer side wall of each signal shielding cabinet body, and a temperature monitoring device is arranged inside each signal shielding cabinet body. The temperature adjusting equipment is connected with the temperature monitoring equipment;

the temperature monitoring equipment is used for detecting the temperature in the signal shielding cabinet body, generating a control command based on the detected temperature and sending the control command to the temperature adjusting equipment, so that the temperature adjusting equipment adjusts the temperature in the signal shielding cabinet body based on the control command. In specific implementation, the temperature in the signal shielding cabinet body can be controlled to be about 20 ℃.

In addition, fire extinguishing equipment can be arranged in each signal shielding cabinet body and used for conducting fire extinguishing treatment on the testing equipment in the signal shielding cabinet body when batteries of the testing equipment explode or catch fire. In the specific implementation, fire extinguishing equipment utilizing heptafluoropropane to extinguish fire can be arranged in the signal shielding cabinet body.

In addition, an access control device may be provided outside each signal shielding cabinet, and with this access control device, the signal shielding cabinet may be opened only with a predetermined access control card, for example, an employee card.

Above-mentioned real quick-witted cloud surveys rack area is little to need not set up the specific opening that is used for hardware facilities maintenance and change on the signal shielding cabinet body, but utilize rotatable base, just can rotate the test equipment that needs the observation in the testing process or the hardware facilities that will need the maintenance to change to same preset opening position department, realized utilizing same opening to realize functional test and equipment maintenance simultaneously, improved the signal shielding effect between the different signal shielding cabinet bodies in this real quick-witted cloud surveys rack. In addition, the real machine cloud measurement cabinet adopts a layered structure, and the problem of disorder wire arrangement in the prior art can be solved by using the wire arrangement device.

The foregoing description of the various embodiments is intended to highlight various differences between the embodiments, and the same or similar parts may be referred to one another, which are not repeated herein for brevity.

The modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical units, may be located in one position, or may be distributed on multiple network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present disclosure may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

The above are only specific embodiments of the present disclosure, but the scope of the present disclosure is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present disclosure, and shall cover the scope of the present disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (10)

1. A real machine cloud measurement cabinet is characterized by comprising at least one signal shielding cabinet body, wherein a rotatable base is arranged in the signal shielding cabinet body; the rotatable base is provided with an equipment supporting frame for supporting test equipment and communication equipment for communicating the test equipment with remote equipment; the communication equipment transmits the test information of the test equipment to the remote equipment so that the remote equipment tests the test equipment based on the test information;

the test equipment and the communication equipment are positioned at different positions of the equipment support frame;

the rotatable base is used for rotating the test equipment or the communication equipment to the same preset opening position of the signal shielding cabinet body.

2. The real-machine cloud testing cabinet of claim 1, wherein the signal shielding cabinet further comprises a rotatable support frame connected with the rotatable base;

the rotatable support frame is used for driving the rotatable base to rotate.

3. The real-machine cloud testing cabinet of claim 2, wherein the signal shielding cabinet body further comprises a power line, a network cable, a filter and a power supply device;

the power line and the network cable penetrate through the rotatable support frame, one end of the power line is connected with the power supply equipment, the other end of the power line is connected with the filter, and the filter is connected with an external power supply; one end of the network cable is connected with the communication equipment, and the other end of the network cable is connected with external network equipment;

an opening is formed in the rotatable supporting frame and used for replacing the power line or the network cable.

4. The real-machine cloud test cabinet of any one of claims 1 to 3, wherein at least one supporting part for supporting the test equipment, at least one wire arranging device and at least one wire collecting device are arranged on the equipment supporting frame; a plurality of equipment supporting seats are arranged on the supporting part, and each equipment supporting seat is used for supporting one piece of test equipment;

each supporting seat is provided with a communication connecting line connected with the test equipment; the communication connecting line is connected with the hub through the wire arranging device.

5. The cabinet of claim 4, wherein the support portion is parallel to a longest line on the rotatable base.

6. The real machine cloud measurement cabinet according to claim 4, wherein the equipment support base is a groove-type support base comprising two side walls forming a groove and a bottom plate; both of the two side walls are movably connected to the bottom plate;

the communication connecting line is arranged in the groove of the equipment supporting seat.

7. The live cloud testing cabinet of claim 4, wherein the signal shielding cabinet body further comprises a data barrel post; the equipment support frame is also provided with at least one processor, at least one concentrator data line, at least one processor power line, at least one concentrator power line and a processor communication line;

the processor is connected with the hub through the hub data line;

the processor power line and the processor communication line both penetrate through the data barrel column and are connected with the processor; the hub power line penetrates through the data barrel column to be connected with the hub;

the processor communication line is connected with the processor and the communication device.

8. The real machine cloud measurement cabinet according to claim 7, wherein at least one supporting beam is further arranged on the equipment supporting frame, and the supporting beam and the supporting part are respectively located at positions corresponding to two sides of the equipment supporting frame;

the processor and the hub are arranged on the supporting beam.

9. The real machine cloud measurement cabinet according to claim 4, wherein the support part comprises a support bottom plate and a support baffle; the equipment supporting seat is arranged on the supporting bottom plate, and the supporting baffle is arranged on the upper side of the supporting bottom plate and used for preventing the test equipment from toppling.

10. The real-machine cloud testing cabinet of claim 1, further comprising at least one temperature regulating device and at least one temperature monitoring device;

the temperature adjusting device is arranged on the outer side wall of the signal shielding cabinet body, the temperature monitoring device is arranged inside the signal shielding cabinet body, and the temperature adjusting device is connected with the temperature monitoring device;

the temperature monitoring equipment is used for detecting the temperature in the signal shielding cabinet body, generating a control command based on the detected temperature and sending the control command to the temperature adjusting equipment, so that the temperature adjusting equipment adjusts the temperature in the signal shielding cabinet body based on the control command.

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