CN109757089B - Central server heat abstractor based on big data - Google Patents

Abstract

The invention discloses a central server heat dissipation device based on big data, which comprises a heat radiator, a fixing frame, an electric wire, a wiring end, sponge cushion layers and a working cavity, wherein the heat radiator and the wiring end are both in a cuboid structure, the fixing frame is welded at the upper end of the heat radiator, the back of the heat radiator is provided with a wiring port for connecting the electric wire, the working cavity is formed between the two sponge cushion layers, the working cavity is respectively provided with a signal port, a signal contact, a server, an inner limiting ring, an auxiliary driving mechanism and an outer fixing ring, two sides of the signal port are respectively provided with the signal contact, the wiring end is matched with the signal port, the signal contact and the server together, the server forms three-way signals by utilizing the signal port and two signal contacts, two signal circuits are arranged in the server for butting the signal contacts, and the central server is started by utilizing the two signal contacts, the motor burnout caused by the continuous operation of the motor due to the stop of heat dissipation is avoided.

Description

Central server heat abstractor based on big data

Technical Field

The invention relates to the field of driving heat dissipation of electric automobiles, in particular to a central server heat dissipation device based on big data.

Background

There are many electric automobiles, motors also have many kinds, and for the heat dissipation mode of motors mainly there are wind cooling and water cooling, theoretically all motors can adopt wind cooling or water cooling, because electric automobile power is relatively big, the load is big, and the car length should reach the engine load standard.

The liquid cooling motor needs to add extra devices such as electric water pump and radiator now and comes to provide the cooling for the motor, because the component structure of this multiple device is comparatively complicated, consequently all there is a control center operation for the drive of simplifying the device, the heat dissipation cooling system who constitutes devices such as electric water pump and radiator is controlled by data center server, all circuit system all converge to data center server and handle, because data center server mainly installs in automobile body, and data center server docks by a signal point, long-term the use, the signal point is impaired and hinders the unable concrete part of discovering the damage in mounted position and in time handles again, the heat that leads to the motor to produce when the operation can not effectively dispel, just can cause the motor to burn indirectly.

Disclosure of Invention

In order to solve the problems, the invention provides a central server heat dissipation device based on big data.

In order to achieve the purpose, the invention is realized by the following technical scheme: a central server heat dissipation device based on big data comprises a heat radiator, a fixing frame, an electric wire, a wiring end, sponge cushion layers and a working cavity, wherein the heat radiator and the wiring end are of cuboid structures, the fixing frame is welded at the upper end of the heat radiator, a wiring port for connecting the electric wire is arranged at the back of the heat radiator, the working cavity is formed between the two sponge cushion layers, a signal port, a signal contact, a server, an inner limiting ring, an auxiliary driving mechanism and an outer fixing ring are respectively arranged in the working cavity, the two sides of the signal port are respectively provided with the signal contact, the signal contact and the server are of an integrated structure, the bottom end of the outer surface of the server is supported and fixed through the outer fixing ring, the outer fixing ring and the inner limiting ring are of semicircular structures, and two auxiliary driving mechanisms with the same structure size are arranged between the inner limiting ring and the, wherein supplementary actuating mechanism mainly includes signal feeler lever, supplementary pressure spring, bevel angle, moulding handle, the one end and the supplementary pressure spring of bevel angle are fixed, and the other end is spacing and be 30 fixed through moulding handle, be connected with the signal feeler lever between moulding handle and the interior spacing collar.

As a further improvement of the invention, a plurality of contacts connected with the wiring terminal signals are arranged in the signal port, wherein the bottoms of the contacts are fixed in the outer protective layer through the signal conduction layer.

As a further improvement of the invention, the two sides of the signal conducting layer are electrically connected with signal contacts, and the signal contacts and the signal ports form a double-signal connecting port of a connecting terminal.

As a further improvement of the invention, a clearance distance of 5cm is reserved between the inner limiting ring and the outer fixing ring, and a slot which is in clearance fit with the signal contact rod is arranged between the inner limiting ring and the outer fixing ring.

As a further development of the invention, the two signal contacts are of identical length.

As a further improvement of the invention, the shaping handle is made of thermosetting plastic, so that the shaping handle can be softened when the shaping handle is subjected to the melting point value of the shaping handle, and the fixity of the shaping handle is reduced.

As a further improvement of the invention, the fixing frame is of an inverted L-shaped structure, and the two fixing frames are uniformly distributed at the upper end of the radiator, so that the stability and firmness of the radiator during installation are improved.

As a further improvement of the invention, the shaping handle is used for pressing the inclined corner at one end far away from the inner limiting ring, the pressure of the shaping handle and the elasticity of the auxiliary pressure spring are balanced with each other, and the inclined corner is enabled to correspond to the signal contact rod but not to be contacted with the signal contact rod.

As a further improvement of the invention, one end of the signal contact rod extending out of the outer fixing ring is matched with the signal contact, so that the signal contact is triggered.

Compared with the prior art, the invention has the following beneficial effects:

1. the wiring end of the invention is matched with the signal port, the signal contact and the server together, the server forms three paths of signals by utilizing the signal port and the two signal contacts, two signal circuits are arranged in the server and are used for butting the signal contacts, and when the signal port is damaged, short-circuited or broken, the server is started by utilizing the two signal contacts, thereby avoiding the motor burnout caused by the continuous operation of the motor due to the stop of heat dissipation.

2. The signal contact rod is matched with the shaping handle, the inclined corner and the auxiliary pressure spring together, the signal contact rod keeps signal disconnection with the signal contact by utilizing the shaping handle, when a signal port is disconnected and the internal heat gradually rises to reach the melting point of the shaping handle, the shaping handle is softened, so that the fixation of the signal contact rod and the inclined corner is released, the auxiliary pressure spring bounces, the signal connection of the signal contact rod and the signal contact is realized, the heat dissipation system is restarted, and a plurality of layers of guarantee is provided for the driving of the heat dissipation system.

3. The outer fixing ring and the inner limiting ring are respectively matched with a server and a signal feeler lever, and the outer fixing ring is utilized to provide a fixing fulcrum for the server; and the inner limiting ring is provided with a fixed-size notch to limit the signal feeler lever within a certain moving range, so that effective triggering of the signal feeler lever and the signal contact is guaranteed.

4. The server is arranged in the working cavity formed by the two sponge cushion layers, and the two sponge cushion layers can effectively prevent the server from being impacted by external force due to bumping in the driving process of the electric automobile.

5. The signal conducting layer is of a double-layer structure, wherein each layer is matched with one half of equally-divided contacts, and each layer corresponds to one signal contact, so that each signal contact controls the operation of the heat dissipation device in two batches, and the short circuit of a circuit caused by the large load existing in a single control point is avoided.

Drawings

Fig. 1 is a schematic view of an appearance structure of a central server heat dissipation device based on big data according to the present invention.

Fig. 2 is a schematic view of the internal structure of the heat sink of the present invention.

FIG. 3 is an enlarged view of the structure A in FIG. 2 according to the present invention.

FIG. 4 is a schematic top view of the signal port of the present invention.

In the figure: the device comprises a radiator-1, a fixing frame-2, an electric wire-3, a terminal-4, a sponge cushion layer-5, a working cavity-6, a signal port-41, a signal contact-42, a server-43, an inner limiting ring-61, an auxiliary driving mechanism-62, an outer fixing ring-63, a signal contact rod-621, an auxiliary pressure spring-622, an inclined corner-623, a shaping handle-624, a contact-411, a signal conducting layer-412 and an outer protective layer-413.

Detailed Description

In order to make the technical means, the creation features, the achievement objects and the effects of the present invention easy to understand, fig. 1 to fig. 4 schematically show the structure of the efficient heat dissipation device according to the embodiment of the present invention, and the present invention is further described below with reference to the specific embodiments.

Examples

As shown in fig. 1-3, the present invention provides a central server heat dissipation device based on big data, which includes a heat sink 1, a fixing frame 2, an electric wire 3, a terminal 4, sponge cushion layers 5, and a working chamber 6, wherein the heat sink 1 and the terminal 4 are both in a rectangular parallelepiped structure, the fixing frame 2 is welded at the upper end of the heat sink 1, a wiring port for connecting to the electric wire 3 is arranged on the back surface of the heat sink 1, the working chamber 6 is formed between the two sponge cushion layers 5, the working chamber 6 is respectively provided with a signal port 41, a signal contact 42, a server 43, an inner spacing ring 61, an auxiliary driving mechanism 62, and an outer fixing ring 63, the signal contact 42 is respectively arranged on two sides of the signal port 41, wherein the signal contact 42 and the server 43 are in an integrated structure, the bottom end of the outer surface of the server 43 is supported and fixed by, outer retainer plate 63 is semicircular structure with interior spacing collar 61 install the supplementary actuating mechanism 62 of two equal structure sizes between interior spacing collar 61 and the working chamber 6, wherein supplementary actuating mechanism 62 mainly includes signal feeler lever 621, supplementary pressure spring 622, oblique corner 623, moulding handle 624, the one end and the supplementary pressure spring 622 of oblique corner 623 are fixed, and the other end is spacing and be 30 fixed through moulding handle 624, be connected with signal feeler lever 621 between moulding handle 624 and the interior spacing collar 61.

A gap distance of 5cm is reserved between the inner limiting ring 61 and the outer fixing ring 63, and a slot which is in clearance fit with the signal contact rod 621 is arranged between the inner limiting ring 61 and the outer fixing ring 63.

The lengths of the two signal contact bars 621 are identical.

The shaping handle 624 is made of thermosetting plastic, so that the shaping handle 624 can be softened when receiving the melting point value of the shaping handle, and the fixity of the shaping handle 624 is reduced.

The fixing frame 2 is of an inverted L-shaped structure, and the two fixing frames 2 are uniformly distributed at the upper end of the radiator 1, so that the stability and firmness of the radiator 1 during installation are improved.

The shaping handle 624 is used for pressing the inclined corner 623 at the end away from the inner limiting ring 61, so that the pressure of the shaping handle and the elasticity of the auxiliary pressure spring 622 are balanced, and the inclined corner 623 and the signal contact rod 621 are enabled to be corresponding but not in contact.

The end of the signal contact bar 621 extending out of the outer fixing ring 63 is engaged with the signal contact 42, thereby activating the signal contact 42.

As shown in fig. 4, a plurality of contacts 411 connected with the terminal 4 are disposed in the signal port 41, wherein the bottom of the contacts 411 is fixed in the outer protective layer 413 through the signal conducting layer 412.

The signal contact 42 is electrically connected to both sides of the signal conducting layer 412, and forms a dual signal connection port of the terminal 4 with the signal port 41.

The working principle of the efficient heat dissipation device in the above technical solution is explained as follows:

the radiator 1 and the wiring terminal 4 are used as a data center, the server 43 in the radiator 1 is used as a data center server, all radiating nodes are finally collected to the server 43 for control, and the radiating system formed by the radiating nodes such as a water pump, a cooling fan, a kettle and the like facing the data center server acts simultaneously to ensure the efficient radiating of motor driving, when the equipment operates, the wiring terminal 4 is butted with a control panel of an electric automobile to ensure that the server 43 in the radiator 1 can be safely started, and when the server 43 is started, the signal port 41 is communicated with all wires 3, and the radiating system operates;

in the invention, two matched signal contacts 42 are additionally designed in the server 43, and the two signal contacts 42 respectively control different heat dissipation nodes, so that when the signal port 41 is paralyzed, the heat dissipation stops, the temperature of the motor gradually rises until the melting point of the shaping handle 624 is reached, the shaping handle 624 becomes soft, and therefore, under the elastic force matching of the inclined corner 623 fixed by the shaping handle 624 and the signal contact bar 621 under the auxiliary pressure spring 622, the inclined corner 623 bounces to eject the signal contact bar 621 to be communicated with the signal contacts 42, and the server 43 is restarted to ensure that the heat dissipation work can be accurately carried out.

The features of the embodiments described above may be combined in any combination and for the sake of brevity, all possible combinations of features in the above-described embodiments are not described in detail, however, the combination of features is not to be regarded as a contradiction, but rather as a scope of the present description, and the embodiments are therefore to be regarded in all respects as illustrative rather than restrictive, the scope of the present invention being defined by the appended claims rather than the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (5)

1. The utility model provides a central server heat abstractor based on big data, its structure includes radiator (1), mount (2), electric wire (3), wiring end (4), sponge bed course (5), working chamber (6), its characterized in that: the radiator (1) and the wiring end (4) are of a cuboid structure, a fixing frame (2) is welded at the upper end of the radiator (1), a wiring port used for being connected to an electric wire (3) is arranged at the back of the radiator (1), a working chamber (6) is formed between the two sponge cushion layers (5), a signal port (41), a signal contact (42), a server (43), an inner limiting ring (61), an auxiliary driving mechanism (62) and an outer fixing ring (63) are respectively arranged in the working chamber (6), the signal contacts (42) and the server (43) are of an integrated structure, the bottom end of the outer surface of the server (43) is supported and fixed through the outer fixing ring (63), and the outer fixing ring (63) and the inner limiting ring (61) are of semicircular structures, two auxiliary driving mechanisms (62) with the same structure and size are mounted between the inner limiting ring (61) and the working cavity (6), wherein each auxiliary driving mechanism (62) comprises a signal contact rod (621), an auxiliary pressure spring (622), an oblique corner (623) and a shaping handle (624), one end of each oblique corner (623) is fixed with the auxiliary pressure spring (622), the other end of each oblique corner is limited by the shaping handle (624) and fixed at 30 degrees, and the signal contact rod (621) is connected between the shaping handle (624) and the inner limiting ring (61); the shaping handle is made of thermosetting plastic, and when the temperature rises to the melting point of the shaping handle, the shaping handle becomes soft, the signal contact rod is jacked up by the inclined corner under the elastic matching of the auxiliary pressure spring, so that the signal contact rod is communicated with the signal contact point, and the server is restarted to work.

2. The big data based center server heat dissipation device as recited in claim 1, wherein: a plurality of contacts (411) connected with the terminal (4) in a signal mode are arranged in the signal port (41), and the bottoms of the contacts (411) are fixed in the outer protective layer (413) through the signal conduction layer (412).

3. The big data based center server heat dissipation device as claimed in claim 2, wherein: and two sides of the signal conducting layer (412) are electrically connected with signal contacts (42) to form a double-signal conducting port of the terminal (4) together with the signal port (41).

4. The big data based center server heat dissipation device as recited in claim 1, wherein: a gap distance of 5cm is reserved between the inner limiting ring (61) and the outer fixing ring (63), and a groove which is in clearance fit with the signal contact rod (621) is formed between the inner limiting ring (61) and the outer fixing ring (63).

5. The big data based center server heat sink according to claim 1 or 4, wherein: the lengths of the two signal contact rods (621) are consistent.

Images