CN220858789U - Micro OLED temperature control platform - Google Patents

Abstract

The utility model provides a Micro OLED temperature control platform, which comprises a temperature control mechanism arranged on the back surface of a Micro OLED body, wherein the temperature control mechanism comprises a mounting block fixedly arranged on the back surface of the Micro OLED body through a mounting assembly, a refrigerating assembly vertically penetrating through the mounting block and arranged on the end surface of one end far away from the Micro OLED body, and a heat dissipation assembly arranged on the mounting block and used for conveying cold air produced by the refrigerating assembly to all positions on the back surface of the Micro OLED body; the mounting block is attached to the end face of the Micro OLED body, a heat dissipation groove is formed in the end face of the Micro OLED body, an exhaust port penetrating through the heat dissipation groove and the outside of the mounting block is formed in the side wall of the heat dissipation groove, and an exhaust filter plate is arranged at the opening position of the exhaust port; the refrigerating end of the refrigerating component is arranged in the radiating groove in a penetrating way; according to the Micro OLED body cooling device, the Micro OLED body can be conveniently cooled, the situation that heat is accumulated on the Micro OLED body is avoided, and the service life of the Micro OLED body is guaranteed.

Description

Micro OLED temperature control platform

Technical Field

The utility model relates to the technical field of display temperature control equipment, in particular to a Micro OLED temperature control platform.

Background

Micro OLED (Organic LIGHT EMITTING DISPLAY) is called black horse of next generation display technology, has been widely used in military markets such as helmets, gun sight, night vision devices, etc., and Micro OLED Micro displays will be exploded with the application of new technologies such as AR/VR and autopilot. Most of the existing terminal products in the market are head-mounted or wearable devices. In future applications, with the increasing market, not only the army field, but also Micro OLED displays must be used in a multi-medium extreme environment. Including extremely cold or extremely hot environments.

The Micro OLED display technology refers to a display technology that self-luminous Micro-scale OLED is taken as a luminous pixel unit, and the luminous pixel unit is assembled on a driving panel to form a high-density OLED array. Due to the characteristics of small size, high integration level, self-luminescence and the like of the Micro OLED chip, compared with an LCD and an OLED, the Micro OLED chip has the advantages of being larger in brightness, resolution, contrast, energy consumption, service life, response speed, thermal stability and the like, the traditional Micro OLED display screen is poor in heat dissipation effect, heat accumulation occurs to accelerate aging of the Micro OLED display screen, and the service life of the Micro OLED display screen is shortened.

Disclosure of utility model

Aiming at the technical problems, the Micro OLED temperature control platform provided by the utility model can conveniently dissipate heat and cool the Micro OLED body, avoids the occurrence of heat accumulation on the Micro OLED body, and ensures the service life of the Micro OLED body.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the temperature control mechanism comprises a mounting block fixedly mounted on the back surface of the Micro OLED body through a mounting assembly, a refrigerating assembly vertically penetrating through the mounting block and arranged on the end surface of one end far away from the Micro OLED body, and a heat dissipation assembly arranged on the mounting block and used for conveying cold air produced by the refrigerating assembly to all positions on the back surface of the Micro OLED body; the mounting block is attached to the end face of the Micro OLED body, a heat dissipation groove is formed in the end face of the Micro OLED body, an exhaust port penetrating through the heat dissipation groove and the outside of the mounting block is formed in the side wall of the heat dissipation groove, and an exhaust filter plate is arranged at the opening position of the exhaust port; the refrigerating end of the refrigerating component penetrates through the radiating groove.

Preferably, the installation component includes four sucking discs that set up in the installation piece laminating Micro OLED body terminal surface offer the seal groove, one end fixed connection sucking disc other end activity run through in the outside control lever of installation piece to and set up in the seal groove and the cover locate the reset spring on the control lever, reset spring both ends are fixed connection sucking disc's seal groove diapire respectively.

Preferably, the mounting block is far away from the second mounting groove that link up with the heat dissipation groove on the Micro OLED body one end terminal surface, and the radiating component is provided with the drive radiator fan and carries out pivoted radiator motor including the erection column that can fix setting in the second mounting groove, set up on the erection column side sets up a plurality of air inlet groove open position, set up on the erection column is close to mounting block one end terminal surface and link up with a plurality of air inlet grooves to and set up the radiator fan in the collection groove, on the erection column is kept away from mounting block one end terminal surface.

Preferably, the heat dissipation assembly further comprises a rotating ring which is arranged on the end face of one end of the mounting block in a rotating way, a rotating ring which is arranged on the end face of the mounting block and is fixedly connected with the rotating ring, and a plurality of guide plates which are arranged on the side face of the rotating ring in a one-to-one correspondence way and are arranged in a plurality of guide grooves in a circumferential array way, the length directions of the guide plates are 30 degrees in the direction of the center line of the rotating ring, and the guide plates are arranged on the rotating ring in a circumferential array way.

Preferably, the refrigerating assembly comprises a mounting ring which is arranged on the end face of one end of the Micro OLED body away from the mounting block and penetrates through the first mounting groove with the heat dissipation groove, and a plurality of semiconductor refrigerating sheets which are arranged on the end face of the mounting block, wherein the semiconductor refrigerating sheets are arranged on the mounting ring, and the length directions of the semiconductor refrigerating sheets are all in the axial direction of the mounting ring.

The utility model has the beneficial effects that: wherein directly install the installation piece and fix at Micro OLED body, accelerate the flow velocity of air on Micro OLED body back through the radiating component who sets up on the installation piece, thereby be convenient for accelerate the radiating efficiency to Micro OLED body, and through the refrigeration component who sets up on the installation piece, thereby be convenient for reduce through Micro OLED body back flow air's temperature, thereby be convenient for cool down the heat dissipation to Micro OLED body, the hot accumulational condition appearance has been avoided in the during operation to Micro OLED body, the ageing condition appears in the messenger Micro OLED body, the cooling of dispelling the heat to Micro OLED body that can be convenient has avoided the heat to appear at the accumulational condition on Micro OLED body, the life of Micro OLED body has been guaranteed.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate and together with the embodiments of the utility model and do not constitute a limitation to the utility model, and in which:

fig. 1 is a schematic diagram of a Micro OLED temperature control platform according to the present utility model.

Fig. 2 is a schematic structural diagram of a temperature control mechanism according to the present utility model.

Fig. 3 is a schematic structural diagram of a refrigeration assembly and a heat dissipation assembly according to the present utility model.

In the figure: 1. a Micro OLED body; 2. a mounting block; 3. an exhaust port; 4. an exhaust filter plate; 5. a control lever; 6. a first mounting groove; 7. a mounting ring; 8. a semiconductor refrigeration sheet; 9. a second mounting groove; 10. a mounting column; 11. an air inlet groove; 12. an air inlet filter plate; 13. a heat dissipation motor; 14. sealing grooves; 15. a suction cup; 16. a heat sink; 17. a rotating ring; 18. a guide groove; 19. a guide plate; 20. a collection trough; 21. a heat radiation fan; 22. the groove is rotated.

Detailed Description

In order that the manner in which the above recited features, objects and advantages of the present utility model are attained and can be readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings, but which are appended drawings. Based on the examples in the embodiments, those skilled in the art can obtain other examples without making any inventive effort, which fall within the scope of the utility model.

Referring to fig. 1-3, a Micro OLED temperature control platform includes a temperature control mechanism disposed on a back surface of a Micro OLED body 1, the temperature control mechanism includes a mounting block 2 fixedly mounted on the back surface of the Micro OLED body 1 through a mounting component, a cooling component vertically penetrating through the mounting block 2 and disposed on an end surface of one end of the mounting block 2 far away from the Micro OLED body 1, and a heat dissipation component disposed on the mounting block 2 and used for conveying cold air produced by the cooling component to all positions on the back surface of the Micro OLED body 1; the mounting block 2 is attached to the end face of the Micro OLED body 1, a heat dissipation groove 16 is formed in the end face of the Micro OLED body, an exhaust port 3 penetrating through the heat dissipation groove 16 and the outside of the mounting block 2 is formed in the side wall of the heat dissipation groove 16, and an exhaust filter plate 4 is arranged at the opening position of the exhaust port 3; the refrigeration end of the refrigeration assembly is disposed through the heat sink 16.

As shown in fig. 1-3, the mounting block 2 is directly mounted and fixed on the back of the Micro OLED body 1, the air flow speed in the heat dissipation groove 16 is conveniently accelerated through the heat dissipation component arranged on the mounting block 2, and air can pass through the exhaust filter plate 4 arranged on the opening position of the exhaust port 3 formed on the side surface of the mounting block 2, so that dust in the outside air is prevented from entering the heat dissipation groove 16 through the exhaust filter plate 4, and is accumulated on the back of the Micro OLED body 1 in the heat dissipation groove 16, so that the situation that the Micro OLED body 1 is inconvenient to transfer heat is caused, and the mounting block 2 is provided with the refrigeration component, so that the temperature of the air in the air flow is conveniently reduced, the Micro OLED body 1 is conveniently cooled, the cooling efficiency is improved, the situation that heat is accumulated on the Micro OLED body 1 is avoided, and the service life of the Micro OLED body 1 is ensured.

As shown in fig. 1-2, the installation component includes four suckers 15 arranged in a sealing groove 14 formed in the end face of the Micro OLED body 1 and attached to the installation block 2, a control rod 5 with one end fixedly connected with the suckers 15 and the other end movably penetrating through the outside of the installation block 2, and a reset spring arranged in the sealing groove 14 and sleeved on the control rod 5, wherein two ends of the reset spring are respectively fixedly connected with the bottom wall of the sealing groove 14 of the suckers 15, when the installation block 2 is installed and fixed on the Micro OLED body 1, the end face of the installation block 2, provided with a heat dissipation groove 16, is directly attached to the Micro OLED body 1, and then the suckers 15 and the reset spring are pressed by the control rod 5, so that the suckers 15 penetrating through the sealing groove 14 are adsorbed on the back face of the Micro OLED body 1, and the installation block 2 is conveniently installed and fixed on the Micro OLED body 1, and the Micro OLED body 1 is conveniently cooled by a heat dissipation component and a refrigerating component on the installation block 2.

As shown in fig. 1-3, the mounting block 2 is far away from the second mounting groove 9 which is communicated with the heat dissipation groove 16 and is arranged on the end face of one end of the Micro OLED body 1, the heat dissipation component comprises a mounting column 10 which can be fixedly arranged in the second mounting groove 9, an air inlet filter plate 12 which is arranged on the side face of the mounting column 10 and is provided with a plurality of air inlet grooves 11, a collecting groove 20 which is arranged on the end face of the mounting column 10 close to the mounting block 2 and is communicated with the plurality of air inlet grooves 11, and a heat dissipation fan 21 which is arranged in the collecting groove 20, a heat dissipation motor 13 which is used for driving the heat dissipation fan 21 to rotate is arranged on the end face of the mounting column 10, after the mounting block 2 is fixedly arranged on the Micro OLED body 1, the heat dissipation motor 13 which is arranged on the mounting column 10 drives the heat dissipation fan 21 to rotate, so that air can be conveniently filtered through the air inlet filter plate 12, and sucked into the collecting groove 20, so that air can be conveniently blown into the back face of the Micro OLED body 1, and dust can be conveniently cooled down by the air filter plate 12, and dust can be conveniently filtered into the back face of the Micro OLED body 1.

As shown in fig. 1-2, the heat dissipation assembly further comprises a rotating ring which is arranged on the end face of one end of the mounting post 10 and is jointed with the mounting block 2 and is provided with a rotating groove 22, a rotating ring 17 which is arranged on the end face of the mounting post 10 and is fixedly connected with the rotating ring, and a plurality of guide plates 19 which are arranged on the side face of the rotating ring 17 in a circumferential array manner and are provided with a plurality of guide grooves 18, the length direction of each guide plate 19 is 30 degrees with the central line direction of the rotating ring 17, the guide plates 19 are arranged on the rotating ring 17 in a circumferential array manner, wherein after the cooling fan 21 sucks air outside the mounting post 10 into the collecting groove 20, the guide grooves 18 are provided with the opening position of the guide grooves 18 and are 30 degrees with the axial direction of the rotating ring 17, so that the rotating ring 17 can be driven to rotate on the end face of the mounting post 10 in the air passing through the guide grooves 18, the air is enabled to enter the cooling groove 16 in a rotating state, the cooling groove 16 is enabled to be convenient for carrying out back surface cooling on the Micro OLED body 1, namely the OLED body 1 is enabled to be convenient for carrying out cooling on the Micro OLED body 1, the cooling effect is guaranteed, and the cooling effect of the Micro OLED body 1 is avoided.

As shown in fig. 2-3, the refrigeration assembly comprises a mounting ring 7 arranged on the end surface of one end of the mounting block 2 far away from the Micro OLED body 1 and penetrating through the heat dissipation groove 16 in the first mounting groove 6, and a plurality of semiconductor refrigeration sheets 8 arranged on the inner end surface of the mounting block 2 and positioned on the mounting ring 7, wherein the length directions of the semiconductor refrigeration sheets 8 are all in the axial direction of the mounting ring 7, and the cooling assembly is convenient for blowing the temperature-reduced air onto the back surface of the Micro OLED body 1 after the air flow speed of the semiconductor refrigeration sheets 8 is accelerated through the heat dissipation fan 21, so that the Micro OLED body 1 is cooled and dissipated conveniently, namely, the Micro OLED body 1 is convenient for temperature control operation.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (5)

1. The Micro OLED temperature control platform comprises a temperature control mechanism arranged on the back surface of a Micro OLED body (1), and is characterized by comprising a mounting block (2) fixedly arranged on the back surface of the Micro OLED body (1) through a mounting component, a refrigerating component vertically penetrating through the mounting block (2) and far away from the end surface of one end of the Micro OLED body (1), and a heat dissipation component arranged on the mounting block (2) and used for conveying cold air produced by the refrigerating component to all positions on the back surface of the Micro OLED body (1); the mounting block (2) is attached to the end face of the Micro OLED body (1), a heat dissipation groove (16) is formed in the end face of the Micro OLED body, an exhaust port (3) penetrating through the heat dissipation groove (16) and the outside of the mounting block (2) is formed in the side wall of the heat dissipation groove (16), and an exhaust filter plate (4) is arranged at the opening position of the exhaust port (3); the refrigerating end of the refrigerating component is arranged in the radiating groove (16) in a penetrating way.

2. The Micro OLED temperature control platform of claim 1, wherein: the installation component includes four sucking discs (15) that set up in installing piece (2) laminating Micro OLED body (1) terminal surface offer seal groove (14), one end fixed connection sucking disc (15) other end activity run through in installing piece (2) outside control rod (5), and set up in seal groove (14) and cover locate reset spring on control rod (5), reset spring both ends are fixed connection seal groove (14) diapire of sucking disc (15) respectively.

3. The Micro OLED temperature control platform of claim 2, wherein: the installation piece (2) is kept away from second mounting groove (9) that link up with radiating groove (16) have been seted up on Micro OLED body (1) one end terminal surface, radiating assembly is including installing post (10) that can fix setting in second mounting groove (9), set up on installing post (10) side sets up a plurality of air inlet tank (11) open position air inlet filter board (12), set up on installing post (10) near installation piece (2) one end terminal surface and with a plurality of air inlet tank (11) through collect groove (20), and set up radiator fan (21) in collecting groove (20), be provided with on installing post (10) one end terminal surface of keeping away from installation piece (2) and drive radiator fan (21) and carry out pivoted radiator motor (13).

4. A Micro OLED temperature control platform according to claim 3, wherein: the heat dissipation assembly further comprises a rotating ring which is arranged on the end face of one end of the mounting column (10) in a laminating manner and provided with a rotating groove (22), a rotating ring (17) which is arranged on the end face of the mounting column (10) and fixedly connected with the rotating ring at one end, and a plurality of guide plates (19) which are arranged on the side face of the rotating ring (17) in a one-to-one correspondence manner and are provided with a plurality of guide grooves (18) in a circumferential array manner, the length directions of the guide plates (19) are 30 degrees with the central line direction of the rotating ring (17), and the guide plates (19) are arranged in a circumferential array manner on the rotating ring (17).

5. The Micro OLED temperature control platform of claim 4, wherein: the refrigerating assembly comprises a mounting block (2), a mounting ring (7) which is arranged on the end face of one end of the mounting block (2) away from the Micro OLED body (1) and communicated with the heat dissipation groove (16) in the first mounting groove (6), and a plurality of semiconductor refrigerating sheets (8) which are arranged on the inner end face of the mounting block (2) and are arranged on the mounting ring (7), wherein the length directions of the semiconductor refrigerating sheets (8) are all in the axial direction of the mounting ring (7).