CN212463737U - Active energy-saving and environment-friendly heat dissipation system of biochemical analyzer - Google Patents
Active energy-saving and environment-friendly heat dissipation system of biochemical analyzer Download PDFInfo
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- CN212463737U CN212463737U CN202021405992.3U CN202021405992U CN212463737U CN 212463737 U CN212463737 U CN 212463737U CN 202021405992 U CN202021405992 U CN 202021405992U CN 212463737 U CN212463737 U CN 212463737U
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Abstract
The utility model discloses an active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer, which comprises a box body, a dustproof device, an air intake device, a control device, a refrigeration air channel series structure and a refrigeration air channel synthetic structure, wherein a through hole and a heat dissipation groove on the box body are positioned on opposite surfaces, a baffle covers the through hole, a plurality of air intake grooves are uniformly distributed on the baffle, a dustproof net covers a plurality of air intake grooves, a plurality of heat dissipation fans are rotationally connected with a fan mounting piece, the air intake direction is towards the plurality of air intake grooves, the control device is arranged in the box body and is used for detecting temperature, the refrigeration air channel series structure and the refrigeration air channel synthetic structure are positioned above the box body and between the air intake device and the heat dissipation groove, air is supplied into the box body through the air intake device, the air intake is kept to be more than 50 percent of the, meanwhile, the dustproof net enhances the dustproof effect, so that the heat dissipation and dust prevention can be realized.
Description
Technical Field
The utility model relates to a medical instrument heat dissipation technical field especially relates to a biochemical analyzer's active energy-concerving and environment-protective cooling system.
Background
The full-automatic biochemical immunoassay analyzer is a high-precision instrument which integrates light, mechanical, electronic, software and clinical application technologies and has higher automation degree, on one hand, the precision and the reliability of precision mechanical parts of the instrument are greatly influenced by dust, and the instrument needs to be kept closed as much as possible to prevent dust; on the other hand, many heating components, such as electronic devices, power supplies, light sources, semiconductor refrigeration radiators and the like, need good ventilation environment for heat dissipation, and therefore, the full-automatic biochemical immunoassay analyzer needs good dustproof and heat dissipation system design.
In the existing full-automatic biochemical immunoassay analyzer, the most common method is a mode of implementing a negative pressure heat dissipation system design of forced ventilation, namely, an exhaust fan exhausts air outwards for heat dissipation, the heat dissipation mode can cause the whole or local pressure inside the full-automatic biochemical immunoassay analyzer to be smaller than the external air pressure, an air inlet and a shell of the biochemical analyzer cannot be absolutely sealed, external dust can be sucked into the inside of the analyzer, so that a light path and a reaction cup are polluted, the test precision and high-precision mechanical faults are reduced, the service life of an electronic device is prolonged, the working reliability of the analyzer is further influenced, the maintenance difficulty is increased, and the use and maintenance cost is increased; and the internal structure of the full-automatic biochemical immunoassay analyzer is complicated, and in order to improve the heat dissipation effect, an exhaust fan with large air volume is often needed and the rotating speed is increased, so that high-decibel noise pollution can be brought, and the full-automatic biochemical immunoassay analyzer is not energy-saving and is not environment-friendly.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide an active energy-concerving and environment-protective cooling system of biochemical analyzer aims at solving present full-automatic biochemical immunoassay analyzer cooling system when satisfying the heat dissipation demand, can not improve the problem of dustproof effect.
In order to achieve the above object, the present invention provides an active energy-saving and environment-friendly heat dissipation system for a biochemical analyzer, comprising a box body, a dust-proof device and an air intake device, wherein the box body has a through hole and a plurality of heat dissipation grooves, the through hole is located at one side of the box body, the plurality of heat dissipation grooves are distributed at one side of the box body and are located at opposite sides of the through hole, the dust-proof device comprises a baffle plate and a dust screen, the baffle plate is fixedly connected with the box body and covers the through hole, the baffle plate has an installation slot and a plurality of air intake grooves, the plurality of air intake grooves are uniformly distributed on the baffle plate, the installation slot is located at the periphery of the plurality of air intake grooves, the dust screen is detachably connected with the baffle plate and covers the plurality of air intake grooves and is located in the installation slot, the air intake device is located in the box body, the air intake device comprises, the fan mounting part with the connection can be dismantled to the box to be located and be close to one side of baffle, it is a plurality of radiator fan with fan mounting part rotates to be connected, and the air inlet direction is towards a plurality of the air inlet duct.
The active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a control device, wherein the control device comprises temperature-sensing supports and temperature sensors, the number of the temperature-sensing supports and the number of the temperature sensors are multiple, the temperature-sensing supports are respectively installed on one sides close to the air inlet groove and the reaction disc in the box body, and each temperature sensor is fixedly connected with each temperature-sensing support.
The dustproof net is provided with a handle, and the handle is positioned on one side, far away from the box body, of the baffle.
The box body is provided with two first radiating holes, and the two first radiating holes are positioned on one side close to the radiating groove.
The active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a refrigeration air channel series structure, wherein the refrigeration air channel series structure is communicated with the box body and the two first heat dissipation holes and is positioned between the air inlet device and the two first heat dissipation holes.
Wherein, refrigeration wind channel series connection structure includes two refrigeration wind channel subassemblies, each refrigeration wind channel subassembly with box and each first louvre intercommunication, refrigeration wind channel subassembly includes first air inlet wind channel pipe, air-out wind channel pipe, connection wind channel pipe and two first axial fan, first air inlet wind channel pipe with the box intercommunication, and be located radiator fan air inlet wind direction's top, air-out wind channel pipe with first louvre intercommunication, connect the wind channel pipe with first air inlet wind channel pipe with air-out wind channel pipe intercommunication, and be located first air inlet wind channel pipe with between the air-out wind channel pipe, two first axial fan is located respectively first air inlet wind channel pipe with between the connection wind channel pipe connect the wind channel pipe with between the air-out wind channel pipe.
The box body is also provided with a second heat dissipation hole, and the second heat dissipation hole is positioned at one side close to the first heat dissipation hole.
The active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a refrigeration air channel synthetic structure, wherein the refrigeration air channel synthetic structure is communicated with the box body and the second heat dissipation holes and is positioned between the air inlet device and the second heat dissipation holes.
Wherein, refrigeration wind channel synthetic structure includes two second air inlet air duct pipes, two branch air duct pipes, synthetic air outlet air duct pipe, two second axial fan and third axial fan, two second air inlet air duct pipe with the box intercommunication, and be located radiator fan air inlet wind direction's top, each branch air duct pipe one end and each second air inlet air duct pipe intercommunication, the other end with synthetic air outlet air duct pipe intercommunication, synthetic air outlet air duct pipe with second louvre intercommunication, each second axial fan is located each second air inlet air duct pipe and each between the branch air duct pipe, third axial fan is located synthetic air outlet air duct pipe with between the second louvre.
The utility model discloses an active energy-concerving and environment-protective cooling system of biochemical analyzer, through on the box the through-hole with the radiating groove is located the opposite face, the baffle covers the through-hole, a plurality of the inlet channel evenly distributed is on the baffle, the dust screen covers a plurality of the inlet channel, a plurality of radiator fan with fan mounting part rotates to be connected, and the air inlet direction is towards a plurality of the inlet channel, controlling means sets up in the box and is used for detecting the temperature, refrigeration wind channel series connection structure and the refrigeration wind channel synthetic structure are located above the box, and lie in the air inlet device with between the radiating groove, supply air into the box through the air inlet device, keep the intake to be greater than 50% of the total amount of wind of radiator fan, keep the box inside malleation, with inside heat and dust impurity through the radiating hole, meanwhile, the dustproof net enhances the dustproof effect, so that the heat dissipation and the dustproof are realized, and the problems of energy conservation, environmental protection, low cost, low noise, easy maintenance and the like can be met.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic structural view of an active energy-saving and environment-friendly heat dissipation system of the biochemical analyzer of the present invention;
fig. 2 is a schematic structural view of the active energy-saving and environment-friendly heat dissipation system of the biochemical analyzer in another direction;
FIG. 3 is a schematic structural view of the air intake device of the present invention;
FIG. 4 is a schematic structural view of the dustproof device of the present invention;
fig. 5 is a schematic structural view of the dust screen of the present invention;
fig. 6 is a schematic structural diagram of a refrigerating air duct series structure and a refrigerating air duct composite structure of the present invention;
fig. 7 is a schematic structural diagram of the control device of the present invention;
fig. 8 is a schematic structural view of the adsorption assembly and the cooling fan for adsorbing dust according to the present invention;
FIG. 9 is a partial enlarged view A of FIG. 8;
FIG. 10 is a side view of FIG. 8;
fig. 11 is a schematic structural view of the adsorption assembly and the cooling fan when dust is not adsorbed;
FIG. 12 is a side view of FIG. 11;
in the figure: 1-box body, 2-dustproof device, 3-air inlet device, 4-control device, 5-refrigeration air channel series structure, 6-refrigeration air channel synthetic structure, 11-through hole, 12-heat dissipation groove, 13-first heat dissipation hole, 14-second heat dissipation hole, 21-baffle, 22-dust screen, 23-adsorption component, 31-fan mounting component, 32-heat dissipation fan, 41-temperature-sensing bracket, 42-temperature sensor, 51-refrigeration air channel component, 61-second air inlet air channel pipe, 62-branch air channel pipe, 63-synthetic air outlet air channel pipe, 64-second axial flow fan, 65-third axial flow fan, 211-mounting slot, 212-air inlet slot, 221-handle, 231-first motor, 232-connecting seat, 233 second motor, 234-screw rod, 235-slide block, 236-adsorption tube, 511-first air inlet duct tube, 512-air outlet duct tube, 513-connecting duct tube, 514-first axial fan, 2361-connecting straight tube, 2362-bending tube and 2363-cleaning brush.
Detailed Description
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.
In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. In addition, in the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.
Referring to fig. 1 to 7, the present invention provides an active energy-saving and environment-friendly heat dissipation system for a biochemical analyzer, including a box 1, a dust-proof device 2 and an air intake device 3, wherein the box 1 has a through hole 11 and a plurality of heat dissipation grooves 12, the through hole 11 is located at one side of the box 1, the plurality of heat dissipation grooves 12 are distributed at one side of the box 1 and are located on opposite surfaces of the through hole 11, the dust-proof device 2 includes a baffle 21 and a dust screen 22, the baffle 21 is fixedly connected to the box 1 and covers the through hole 11, the baffle 21 has an installation slot 211 and a plurality of air intake slots 212, the plurality of air intake slots 212 are uniformly distributed on the baffle 21, the installation slot 211 is located at the periphery of the plurality of air intake slots 212, the dust screen 22 is detachably connected to the baffle 21 and covers the plurality of air intake slots 212 and is located in the installation slot 211, air inlet unit 3 is located in the box 1, air inlet unit 3 includes fan installed part 31 and a plurality of radiator fan 32, fan installed part 31 with the connection can be dismantled to the box 1 to be located near one side of baffle 21 is, and is a plurality of radiator fan 32 with fan installed part 31 rotates to be connected, and the air inlet direction is towards a plurality of intake duct 212.
In the present embodiment, the box 1 is a housing of a full-automatic biochemical immunoassay analyzer, and electronic devices, a power supply, a light source, a semiconductor refrigeration heat sink, and the like for analysis are provided inside the box. Dustproof device 2 is used for preventing that external ash layer from getting into in the box 1, air inlet unit 3 is located 1 inside and outside boundary department of box is used for right 1 inside heat dissipation of box is handled. Through-hole 11 is located the front end of box 1 is a plurality of radiating groove 12 is located the rear end of box 1 is located the great part annex of heat production promptly, air inlet unit 3's air-out direction, through-hole 11 and a plurality of radiating groove 12 is located the opposite face, has the radiating effect of convection current. The air inlet device 3 comprises a fan mounting piece 31 and a plurality of heat dissipation fans 32, wherein the fan mounting piece 31 is made by a sheet metal process and is used for mounting the plurality of heat dissipation fans 32, the air inlet direction of the plurality of heat dissipation fans 32 faces towards the plurality of air inlet grooves 212, the air outlet direction faces towards the inside of the box body 1, when the plurality of heat dissipation fans 32 work, the external air enters the inside of the box body 1, the heat and some dust in the inside of the box body 1 are emitted out of the box body 1 through the plurality of heat dissipation grooves 12 along with air flow, the pressure in the inside of the box body 1 is higher than the external air pressure, and the external dust is prevented from entering the inside of the box body 1 through gaps. The dustproof device 2 comprises a baffle 21 and a dustproof net 22, the baffle 21 covers the through hole 11, the baffle 21 is provided with a plurality of air inlet grooves 212, the dustproof net 22 covers a plurality of air inlet grooves 212, namely completely covers the air inlet end of the air inlet device 3, a plurality of installation slots 211 are arranged on the outer side of the air inlet grooves 212, and the dustproof net 22 is positioned in the installation slots 211 and is convenient to replace. It is wherein a plurality of the scope of air inlet duct 212 equals or slightly is greater than air intake device 3's air inlet area, the dress is in the installation slot 211 dust screen 22 covers completely air inlet duct 212 avoids outside dust to pass through air inlet duct 212 gets into inside box 1, just the inboard cotton of baffle 21 is hugged closely air inlet device 3's air inlet end prevents that the air from entering from the side. Specifically, the plurality of heat dissipation fans 32 rotate, the external air passes through the dust screen 22 from the plurality of air inlet grooves 212, and the heat inside the box body 1 is dissipated by the plurality of heat dissipation grooves 12 at the rear end, so that heat dissipation can be realized, and dust prevention can be effectively performed.
The utility model discloses an active energy-concerving and environment-protective cooling system of biochemical analyzer, through on the box 1 through-hole 11 with radiating groove 12 is located the opposite face, baffle 21 covers through-hole 11, and is a plurality of inlet chute 212 evenly distributed is in on the baffle 21, dust screen 22 covers a plurality of inlet chute 212, and is a plurality of radiator fan 32 with fan installed part 31 rotates to be connected, and the air inlet direction is towards a plurality of inlet chute 212, controlling means 4 sets up in be used for detecting the temperature in the box 1, refrigeration wind channel series structure 5 with refrigeration wind channel synthetic structure 6 is located above the box 1, and is located between air inlet unit 3 and radiating groove 12, through air inlet unit 3 toward supplying air in the box 1, keep the intake air volume to be greater than 50% of radiator fan 32 amount of wind sum, keep the inside malleation of box 1, with inside heat and dust impurity through the louvre effluvium, simultaneously dust screen 22 strengthens dustproof effect to the realization can dispel the heat, can prevent dust again, and can satisfy the problem of energy-concerving and environment-protective, with low costs, noise low and requirement such as easy maintenance.
Further, the active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a control device 4, wherein the control device 4 comprises a plurality of temperature-sensitive supports 41 and a plurality of temperature sensors 42, the plurality of temperature-sensitive supports 41 are respectively installed at one side close to the air inlet groove 212 and the reaction disc in the box body 1, and each temperature sensor 42 is fixedly connected with each temperature-sensitive support 41.
In this embodiment, the temperature holder is used to support the temperature sensor 42, the temperature sensor 42 is a sensor capable of sensing temperature and converting into a usable output signal, and is a sensing device with a CPU of an ADC and a corresponding execution circuit, and a sensing portion is not in contact with the temperature sensing holder 41, so as to accurately collect and feed back a temperature state at a certain point inside the box 1. Temperature sensor 42 detects temperature in the box 1 transmits extremely controller in the box 1, controller control with radiator fan 32 driving piece changes the rotational speed and realizes carrying out the heat dissipation according to the circumstances and handle, when the environment the box 1 inside temperature is lower, at this moment can reduce radiator fan 32's rotational speed makes inside and outside air exchange slow down or not exchange, guarantees the inside temperature of box 1 accords with best operating condition, is favorable to the temperature of reaction dish to reach 37 degrees faster and more stable. After the speed of the cooling fan 32 is reduced, the noise is reduced, and the electric energy required by the heating of the reaction disc is synchronously reduced, so that the aims of energy conservation and environmental protection are fulfilled. When the environment and the internal temperature of the box body 1 are high, the temperature control system can increase the rotating speed of the cooling fan 32 according to the feedback temperature, and the optimal working state and the energy-saving effect of the instrument are ensured. The temperature sensor 42 may be of a type 602F-3500F.
Further, the dust screen 22 has a handle 221, and the handle 221 is located on a side of the baffle 21 away from the box body 1.
In this embodiment, the shutter 21 can be freely attached to and detached from the insertion groove 211, and thus, cleaning and maintenance are facilitated without using any tool.
Further, the box body 1 is further provided with two first heat dissipation holes 13, and the two first heat dissipation holes 13 are located at one side close to the heat dissipation groove 12.
In this embodiment, the first heat dissipation hole 13 is disposed at the rear end of the box 1 for accelerating heat dissipation.
Further, the active energy-saving and environment-friendly heat dissipation system of the biochemical analyzer further comprises a refrigeration air channel series structure 5, wherein the refrigeration air channel series structure 5 is communicated with the box body 1 and the two first heat dissipation holes 13 and is positioned between the air inlet device 3 and the two first heat dissipation holes 13.
In this embodiment, the refrigerating duct series structure 5 is located on the large bottom plate at the upper end of the box 1, and is used for directly dissipating the hot air with the intake air volume of the heat dissipation fan 32 through the first heat dissipation hole 13.
Further, the refrigerating air duct series structure 5 comprises two refrigerating air duct assemblies 51, each refrigerating air duct assembly 51 is communicated with the box body 1 and each first heat dissipation hole 13, the cooling air duct assembly 51 includes a first air inlet duct 511, an air outlet duct 512, a connecting duct 513 and two first axial fans 514, the first air inlet duct 511 is communicated with the cabinet 1, and is located above the air inlet direction of the heat dissipation fan 32, the air outlet duct 512 is communicated with the first heat dissipation hole 13, the connecting duct 513 is communicated with the first inlet duct 511 and the outlet duct 512, and is located between first air inlet duct 511 and air outlet duct 512, two first axial fans 514 are located respectively between first air inlet duct 511 and connecting duct 513, connecting duct 513 and air outlet duct 512.
In this embodiment, the cooling air duct series structure 5 includes two cooling air duct assemblies 51, and the two cooling air duct assemblies 51 correspond to the two first heat dissipation holes 13 one by one, and are used for dissipating heat at different positions in the box 1 slightly away from one side of the baffle 21 from the first heat dissipation holes 13 after cooling. Keep away from specifically one side of the opposite face of radiating groove 12, and keep away from slightly one side of baffle 21, box 1 in proper order with first air inlet air duct pipe 511 connect air duct pipe 513 the air-out air duct pipe 512 with first louvre 13 intercommunication, first air inlet air duct pipe 511 with connect between air duct pipe 513 first axial fan 514 is one-level axial fan, connect air duct pipe 513 with between the air-out air duct pipe 512 first axial fan 514 is second grade axial fan, first axial fan 514 is axial fan during operation, and the blade promotes the air and flows in order to the same direction with the axle. The heat in the box 1 is dissipated and flows through the two first axial fans 514 to the first heat dissipation holes 13 and is transferred to the outside of the box 1, so as to further improve the heat dissipation effect.
Further, the box body 1 is further provided with a second heat dissipation hole 14, and the second heat dissipation hole 14 is located at one side close to the first heat dissipation hole 13.
In this embodiment, the second heat dissipation hole 14 is disposed at the rear end of the box 1 for accelerating heat dissipation.
Further, the active energy-saving and environment-friendly heat dissipation system of the biochemical analyzer further comprises a refrigeration air channel synthetic structure 6, wherein the refrigeration air channel synthetic structure 6 is communicated with the box body 1 and the second heat dissipation holes 14 and is positioned between the air intake device 3 and the second heat dissipation holes 14.
In this embodiment, the cooling air duct synthetic structure 6 is located on the large bottom plate at the upper end of the box body 1, and is used for directly dissipating the hot air of the intake air volume of the heat dissipation fan 32 through the second heat dissipation hole 14
Further, the cooling air duct synthetic structure 6 includes two second air inlet duct pipes 61, two branch air duct pipes 62, a synthetic air outlet duct pipe 63, two second axial fans 64 and a third axial fan 65, two second air inlet duct pipes 61 and the box 1 are communicated, and are located above the air inlet direction of the heat dissipation fan 32, each of the branch air duct pipes 62 one end is communicated with each of the second air inlet duct pipes 61, the other end is communicated with the synthetic air outlet duct pipe 63, the synthetic air outlet duct pipe 63 is communicated with the second heat dissipation holes 14, each of the second axial fans 64 is located at each of the second air inlet duct pipes 61 and each of the heat dissipation holes between the branch air duct pipes 62, and the third axial fan 65 is located between the synthetic air outlet duct pipe 63 and the second heat dissipation holes 14.
In this embodiment, two second air inlet duct pipes 61 are located near one side of the baffle 21, and face different directions, so that the thermal gas at different positions flows, and the two second air inlet duct pipes 61, two branch duct pipes 62 are combined into one at last the synthetic air outlet duct pipe 63 is discharged from one of the second heat dissipation holes 14, so as to reduce the number of the second heat dissipation holes 14, prevent the excessive heat dissipation of the first heat dissipation holes 13 and the second heat dissipation holes, and lead to the discharged hot gas to gather at the rear end of the box 1, thus leading to the temperature rise of the box 1. The two second axial fans 64 are primary axial fans, the third axial fan 65 is a secondary axial fan, and when the second axial fans 64 are axial fans, the blades push air to flow in the same direction as the shafts. The heat in the box 1 is dissipated and flows to the second heat dissipation hole 14 through the two second axial fans 64 and the third axial fan 65, and is transferred to the outside of the box 1, so that the heat dissipation effect is further improved.
Further, referring to fig. 8 to 12, the dust-proof device 2 further includes an adsorption component 23, the adsorption component 23 includes a first motor 231, a connection seat 232, a second motor 233, a screw 234, a slider 235 and adsorption tubes 236, the first motor 231 is located in the box body 1, an output end of the first motor 231 is in transmission connection with the connection seat 232, the second motor 233 is located in the connection seat 232, an output end of the second motor 233 is in transmission connection with the screw 234, the screw 234 is in sliding connection with the slider 235 and penetrates through the slider 235, the adsorption tubes 236 are plural, and the adsorption tubes 236 are fixedly connected with the slider 235 and respectively distributed between adjacent blades of the cooling fan 32.
In the present embodiment, the adsorption element 23 is used for adsorbing and cleaning an ash layer on the heat dissipation fan 32 used for a long time, the adsorption element 23 is plural, and each adsorption element 23 corresponds to each heat dissipation fan 32. The first motor 231 and the second motor 233 are electromagnetic devices that convert or transmit electric energy according to the law of electromagnetic induction, and mainly function to generate driving torque to rotate a device connected to the driving torque. The output end of the first motor 231 is in transmission connection with the connecting seat 232, and the first motor 231 is started to drive the connecting seat 232 to rotate. The screw 234 is provided with an external thread, the sliding block 235 is provided with a sliding groove and an internal thread, the second motor 233, the screw 234 and the sliding block 235 form a screw rod structure, the second motor 233 is started to drive the screw 234 to rotate, further the sliding block 235 sleeved on the screw 234 is driven to slide along the extending direction of the screw 234, and the plurality of adsorption tubes 236 are fixedly connected with the sliding block 235, so that the plurality of adsorption tubes 236 are driven to reciprocate along the extending direction of the screw 234. Specifically, when the heat dissipation fan 32 performs a normal heat dissipation operation, the suction pipe 236 is located at a side away from the blades of the heat dissipation fan 32, and does not affect the normal rotation of the blades of the heat dissipation fan 32; when the ash layer adsorption is needed, the heat radiation fan 32 is controlled to stop rotating, the second motor 233 is started to drive the screw 234 to rotate, so that the sliding block 235 moves along the heat radiation fan 32 to enable each adsorption tube 236 to move towards the gap between adjacent blades of the heat radiation fan 32, when the adsorption tube 236 reaches between the adjacent blades, the second motor 233 is stopped to start the first motor 231 to drive the connecting seat 232 to rotate, so that the adsorption tube 236 rotates to be close to the blade on one side of the adjacent blades, the adsorption tube 236 is connected with an adsorption pump outside the box body 1 through a hose, and the hose is good in flexibility, torsion resistance and bending performance and does not affect movement along with the movement of the adsorption tube 236. The adsorption pump is started, and the ash layer on the blades of the cooling fan 32 is adsorbed, so that the cleaning is convenient, the long-term replacement of the cooling fan 32 is avoided, and the detection efficiency and the cost are increased. After the adsorption of the ash layer is completed, the first motor 231 is started again to rotate and reset, so that the adsorption tube 236 is located between adjacent blades and is convenient to withdraw, the second motor 233 is started again to drive the screw 234 to rotate, so as to drive the slider 235 to move towards one side close to the connecting seat 232, so that the adsorption tube 236 is withdrawn between the blades of the cooling fan 32, and the cooling fan 32 is started to continue to rotate and perform cooling treatment.
Further, adsorption tube 236 is including connecting straight tube 2361 and crooked pipe 2362, connect straight tube 2361 with slider 235 fixed connection, crooked pipe 2362 with connect straight tube 2361 integrated into one piece, and towards one side of radiator fan 32 blade.
In this embodiment, curved tube 2362 with connect straight tube 2361 integrated into one piece, stable in structure, curved tube 2362 has the radian, the orientation radiator fan 32 blade does benefit to and closes close to the blade, is convenient for adsorb the ash layer.
Further, adsorption tube 236 still includes cleaning brush 2363, cleaning brush 2363 with connect straight tube 2361 fixed connection, and towards one side of radiator fan 32 blade.
In this embodiment, the cleaning brush 2363 is a tool made of wool, palm, plastic wire, metal wire, or the like, for removing dirt or applying cream. Adsorption tube 236 is located between the adjacent blade, follows connecting seat 232's rotation and when towards the blade, cleaning brush 2363 with the blade contact is scraped, prevents that the ash layer from attaching to on the blade, improves the adsorption effect.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.
Claims (9)
1. An active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer is characterized in that,
the air inlet device is positioned in the box body, the air inlet device comprises a fan mounting piece and a plurality of cooling fans, the fan mounting piece is detachably connected with the box body and positioned on one side close to the baffle plate, the heat dissipation fans are rotatably connected with the fan mounting pieces, and the air inlet direction faces the air inlet grooves.
2. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 1,
the active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a control device, wherein the control device comprises temperature-sensing supports and temperature sensors, the number of the temperature-sensing supports and the number of the temperature sensors are multiple, the temperature-sensing supports are respectively installed at one side close to the air inlet groove and one side of a reaction disc in the box body, and each temperature sensor is fixedly connected with each temperature-sensing support.
3. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 1,
the dustproof net is provided with a handle, and the handle is positioned on one side of the baffle, which is far away from the box body.
4. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 1,
the box body is further provided with two first heat dissipation holes, and the two first heat dissipation holes are located on one side close to the heat dissipation groove.
5. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 4,
the active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a refrigeration air channel series structure, wherein the refrigeration air channel series structure is communicated with the box body and the two first heat dissipation holes and is positioned between the air inlet device and the two first heat dissipation holes.
6. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 5,
the refrigeration wind channel series connection structure comprises two refrigeration wind channel components, each refrigeration wind channel component and the box and each first heat dissipation hole intercommunication, the refrigeration wind channel component comprises a first air inlet wind channel pipe, an air outlet wind channel pipe, a connecting wind channel pipe and two first axial fans, the first air inlet wind channel pipe is communicated with the box and is located above the air inlet direction of the heat dissipation fans, the air outlet wind channel pipe is communicated with the first heat dissipation holes, the connecting wind channel pipe is communicated with the first air inlet wind channel pipe and the air outlet wind channel pipe, and is located between the first air inlet wind channel pipe and the air outlet wind channel pipe, and the two first axial fans are respectively located between the first air inlet wind channel pipe and the connecting wind channel pipe, between the connecting wind channel pipe and between the air outlet wind channel pipes.
7. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 4,
the box body is also provided with second heat dissipation holes, and the second heat dissipation holes are located on one side close to the first heat dissipation holes.
8. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 7,
the active energy-saving environment-friendly heat dissipation system of the biochemical analyzer further comprises a refrigeration air channel synthetic structure, wherein the refrigeration air channel synthetic structure is communicated with the box body and the second heat dissipation holes and is positioned between the air inlet device and the second heat dissipation holes.
9. The active energy-saving and environment-friendly heat dissipation system of a biochemical analyzer according to claim 8,
refrigeration wind channel synthetic structure includes two second air inlet air duct pipes, two branch air duct pipes, synthetic air outlet air duct pipe, two second axial fan and third axial fan, two second air inlet air duct pipe with the box intercommunication, and be located radiator fan air inlet direction's top, each branch air duct pipe one end and each second air inlet air duct pipe intercommunication, the other end with synthetic air outlet air duct pipe intercommunication, synthetic air outlet air duct pipe with second louvre intercommunication, each second axial fan is located each second air inlet air duct pipe and each between the branch air duct pipe, third axial fan is located synthetic air outlet air duct pipe with between the second louvre.
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CN202021405992.3U CN212463737U (en) | 2020-07-16 | 2020-07-16 | Active energy-saving and environment-friendly heat dissipation system of biochemical analyzer |
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