CN218226420U - Press mounting mechanism for air-cooled radiator and element - Google Patents

Abstract

The utility model discloses a belong to pressure equipment technical field, specifically be a pressure equipment mechanism of forced air cooling radiator and component, comprising a base plate, the top middle-end fixed mounting bracing piece of bottom plate, the top fixed mounting roof of bracing piece still includes: the press-fitting assembly is used for simultaneously or separately press-fitting an air-cooled radiator or an element, and is used for placing a placing plate of an air-cooled radiator body or an element, the placing plate is fixedly arranged on both sides of the top of the bottom plate, and the press-fitting assembly comprises: the utility model discloses a press fitting subassembly that is used for placing forced air cooling radiator body or component extruded, the utility model discloses a both ends setting at the roof is used for carrying out simultaneously or separately the pressure equipment subassembly of pressure equipment to forced air cooling radiator or component to and again through the both ends setting at the bottom plate be used for placing the board of placing of forced air cooling radiator body or component, have the effect that the realization can carry out pressure equipment simultaneously or separately the pressure equipment to forced air cooling radiator or component, thereby can reduce cost's input.

Description

Press mounting mechanism for air-cooled radiator and element

Technical Field

The utility model relates to a pressure equipment technical field specifically is a pressure equipment mechanism of forced air cooling radiator and component.

Background

In the mechanical industry, the pressure assembly has an irreplaceable effect in a mechanical manufacturing process flow, and can effectively reduce the equipment requirement, save materials, labor and working time, thereby reducing the production cost of enterprises and improving the production efficiency.

According to the heat pipe press-fitting process structure of the air-cooled radiator disclosed in the Chinese patent CN206024380U and the press-fitting assembly of the semiconductor element disclosed in the Chinese patent CN212113650U, the two groups of press-fitting structures to be used cannot be combined, so that the air-cooled radiator or element can only be separately pressed and cannot be pressed and fitted at the same time, and if the air-cooled radiator or element needs to be pressed and fitted at the same time, a new press-fitting mechanism needs to be added, so that the cost input is increased, and therefore, the press-fitting mechanism of the air-cooled radiator and the element is invented.

SUMMERY OF THE UTILITY MODEL

The present invention has been made in view of the above and/or other problems occurring in the press-fitting mechanism of the prior art air-cooled heat sink and component.

Therefore, the present invention is directed to a press-fitting mechanism for an air-cooled heat sink and an element, which can solve the above-mentioned problems.

For solving the technical problem, according to the utility model discloses an aspect, the utility model provides a following technical scheme:

the utility model provides a pressure equipment mechanism of forced air cooling radiator and component, its includes the bottom plate, the top middle-end fixed mounting bracing piece of bottom plate, the top fixed mounting roof of bracing piece still includes:

the press-fitting assembly is used for simultaneously or separately press-fitting the air-cooled radiator or element;

the placing plates are used for placing the air-cooled radiator body or the element, and the placing plates are fixedly arranged on two sides of the top of the bottom plate.

As an air-cooled radiator and an optimal scheme of pressure equipment mechanism of component, wherein: the pressure equipment subassembly includes:

the lifting assembly is used for extruding a body or an element of the air-cooled radiator, the two ends of the bottom of the top plate are both connected with the lifting assembly, and a placing plate is arranged right below the lifting assembly;

the main driving assembly is used for driving the lifting assembly to rotate and is arranged on the top middle end of the top plate;

driven drive assembly, driven drive assembly is all installed at the top both ends of roof, and driven drive assembly is connected through transmission assembly with drive lifting unit, but driven drive assembly and lifting unit disconnection.

As a forced air cooling radiator and an optimal selection scheme of pressure equipment mechanism of component, wherein: the lifting assembly comprises:

the inner walls of the two ends of the top plate are rotatably connected with the screw rods through bearings;

each group of screw rods is in threaded connection with a nut;

the inner wall of each group of sliding blocks is fixedly provided with a nut;

the supporting shafts are fixedly arranged at two ends of the bottom of each group of sliding blocks;

the supporting shafts are fixedly arranged at two ends of the top of each group of lower pressing plates, and a placing plate is arranged right below each group of lower pressing plates;

be used for avoiding the rotatory guide bar of slider, the two sets of guide bars of the equal fixed mounting in bottom both ends of roof, every group the equal sliding connection guide bar of both ends inner wall of slider.

As a forced air cooling radiator and an optimal selection scheme of pressure equipment mechanism of component, wherein: the main drive assembly includes:

the middle end of the top plate is fixedly provided with the U-shaped plate;

the servo motor is fixedly arranged on the top of the U-shaped plate;

the rotating shaft is rotatably connected to the U-shaped plate through a bearing, and an output shaft of the servo motor is fixedly connected with the rotating shaft with the same diameter.

As a forced air cooling radiator and an optimal selection scheme of pressure equipment mechanism of component, wherein: the driven drive assembly includes:

the two ends of the top plate are fixedly provided with the L-shaped plates;

the L-shaped plates are rotatably connected with the driven shafts through bearings, and each group of driven shafts is connected with the rotating shaft through a transmission assembly;

and the bottom of each driven shaft is fixedly provided with an air cylinder, and the output end of each air cylinder is fixedly provided with an extrusion plate through a piston rod.

As an air-cooled radiator and an optimal scheme of pressure equipment mechanism of component, wherein: and a screw is arranged right below each group of the extrusion plates, and the opposite ends of the extrusion plates and the screws are provided with end face teeth for improving friction force so as to improve the transmission stability.

As a forced air cooling radiator and an optimal selection scheme of pressure equipment mechanism of component, wherein: the transmission assembly is as follows:

the inner wall of the first belt pulley is fixedly provided with a rotating shaft;

and the driven shaft is fixedly arranged on the inner wall of the second belt pulley, and the two groups of second belt pulleys are connected with the first belt pulley in a belt transmission manner.

As a forced air cooling radiator and an optimal selection scheme of pressure equipment mechanism of component, wherein: the transmission assembly is as follows:

the inner wall of the first chain wheel is fixedly provided with a rotating shaft;

and the inner wall of each second chain wheel is fixedly provided with a driven shaft, and the two second chain wheels are in transmission connection with the first chain wheel through chains.

Compared with the prior art:

1. the press-fitting assemblies for simultaneously or separately press-fitting the air-cooled radiator or the element are arranged at the two ends of the top plate, and the placing plates for placing the air-cooled radiator body or the element are arranged at the two ends of the bottom plate, so that the effect of simultaneously or separately press-fitting the air-cooled radiator or the element can be realized, and the investment of cost can be reduced;

2. make main drive assembly drive two sets of driven drive assembly through drive assembly and move, meanwhile, the driven drive assembly of operation can make lifting unit rotate, has the effect that the realization utilizes a set of motor to carry out simultaneous or separately the pressure equipment to forced air cooling radiator or component to can reduce the input quantity of motor, the input of further reduce cost.

Drawings

Fig. 1 is a schematic front view of the structure of embodiment 1 of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1 according to the present invention;

FIG. 3 is a schematic view of the U-shaped plate structure of the present invention;

fig. 4 is a schematic front view of the structure of embodiment 2 of the present invention;

fig. 5 is an enlarged schematic view of the structure at B in fig. 4 according to the present invention.

In the figure: the device comprises a bottom plate 10, a support rod 11, a top plate 12, a main driving assembly 20, a U-shaped plate 21, a servo motor 22, a rotating shaft 23, a transmission assembly 30, a first belt pulley 31, a belt 32, a second belt pulley 33, a first chain wheel 36, a chain 37, a second chain wheel 38, a driven driving assembly 40, an L-shaped plate 41, a driven shaft 42, an air cylinder 43, an extrusion plate 44, a lifting assembly 50, a screw rod 51, a nut 52, a slide block 53, a support shaft 54, a lower pressing plate 55, a guide rod 56 and a placing plate 60.

Detailed Description

To make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Example 1:

the utility model provides a pressure equipment mechanism of forced air cooling radiator and component please refer to and show 1-3, including bottom plate 10, the top middle-end fixed mounting bracing piece 11 of bottom plate 10, the top fixed mounting roof 12 of bracing piece 11 still includes:

the press-mounting assembly is used for simultaneously or separately press-mounting the air-cooled radiator or element;

a placing plate 60 for placing the air-cooled radiator body or element, wherein the placing plate 60 is fixedly arranged on both sides of the top of the bottom plate 10;

the principle is as follows: the air-cooled radiator body and the mounting pieces of the components are respectively placed on the placing plate 60, wherein they can be fixed by a fixing member (such as a bolt) of the related art;

the pressure equipment subassembly includes: the lifting assembly 50 is used for pressing the body or the element on which the air-cooled radiator is placed, the main driving assembly 20 is used for driving the lifting assembly 50 to rotate, and the driven driving assembly 40 is used for driving the lifting assembly 50 to rotate;

lifting unit 50 is all connected at the bottom both ends of roof 12, and is equipped with under lifting unit 50 and places board 60, and main drive assembly 20 is installed on the top middle-end of roof 12, and driven drive assembly 40 is all installed at the top both ends of roof 12, and driven drive assembly 40 is connected through drive assembly 30 with drive lifting unit 50, but driven drive assembly 40 and lifting unit 50 disconnection.

The main drive assembly 20 includes: u-shaped plate 21, servo motor 22, spindle 23;

the middle end of the top plate 12 is fixedly provided with a U-shaped plate 21, a servo motor 22 is fixedly arranged on the top of the U-shaped plate 21, a rotating shaft 23 is rotatably connected to the U-shaped plate 21 through a bearing, and an output shaft of the servo motor 22 is fixedly connected with the rotating shaft 23 with the same diameter;

the principle is as follows: after the air-cooled radiator body and the component mounting members are placed on the placing plate 60, respectively, the rotary shaft 23 is rotated by the servo motor 22.

The transmission assembly 30 is: a first pulley 31, two sets of second pulleys 33;

a rotating shaft 23 is fixedly installed on the inner wall of the first belt pulley 31, a driven shaft 42 is fixedly installed on the inner wall of each group of second belt pulleys 33, and the two groups of second belt pulleys 33 are in transmission connection with the first belt pulley 31 through a belt 32;

the principle is as follows: when the rotating shaft 23 rotates, the two sets of driven shafts 42 are rotated by the first pulley 31, the two sets of second pulleys 33, and the belt 32.

The driven drive assembly 40 includes: an L-shaped plate 41, two sets of driven shafts 42, and a cylinder 43;

the two ends of the top plate 12 are fixedly provided with L-shaped plates 41, each group of L-shaped plates 41 is rotatably connected with a driven shaft 42 through a bearing, each group of driven shafts 42 is connected with the rotating shaft 23 through a transmission assembly 30, the bottom of each group of driven shafts 42 is fixedly provided with a cylinder 43, a piston rod on the cylinder 43 is arranged to be non-rotating, the output end of the cylinder 43 is fixedly provided with an extrusion plate 44 through a piston rod, a screw 51 is arranged right below each group of extrusion plate 44, and the opposite end of the extrusion plate 44 and the screw 51 is provided with end face teeth for improving friction force, so as to improve transmission stability;

the principle is as follows: when the driven shaft 42 rotates, the pressing plate 44 is lowered by the air cylinder 43 until the lowered pressing plate 44 presses the top of the screw 51, and after the pressing, the driven shaft 42 rotates the screw 51.

The elevating assembly 50 includes: the device comprises a screw 51, a nut 52, two groups of sliding blocks 53, a supporting shaft 54, two groups of lower pressing plates 55 and a guide rod 56 for preventing the sliding blocks 53 from rotating;

the inner walls of two ends of the top plate 12 are rotatably connected with screw rods 51 through bearings, nuts 52 are in threaded connection on each group of screw rods 51, the nuts 52 are fixedly installed on the inner wall of each group of sliding blocks 53, supporting shafts 54 are fixedly installed at two ends of the bottom of each group of sliding blocks 53, the supporting shafts 54 are fixedly installed at two ends of the top of each group of lower pressing plate 55, a placing plate 60 is arranged right below each group of lower pressing plate 55, two groups of guide rods 56 are fixedly installed at two ends of the bottom of the top plate 12, and the guide rods 56 are in sliding connection with the inner walls of two ends of each group of sliding blocks 53;

the principle is as follows: before the screw 51 rotates, the heat pipes and the components are fixed on the bottom of the corresponding lower pressing plate 55 by the fixing components (such as bolts) in the prior art, and at the same time, when the screw 51 rotates, the sliding block 53 drives the lower pressing plate 55 on the supporting shaft 54 to descend under the action of the nut 52 until the heat pipes on one group of lower pressing plates 55 are assembled on the air-cooled radiator body on one group of placing plates 60 and the components on the other group of lower pressing plates 55 are assembled on the mounting components of the components on the other group of placing plates 60 by the mounting components, wherein when one group of screws 51 is required not to rotate, the pressing plate 44 is lifted by the corresponding air cylinder 43 until the pressing plate 44 is not in contact with the screw 51.

Example 2:

the utility model provides a press-fitting mechanism of forced air cooling radiator and component, please refer to fig. 4-5, drive assembly 30 is: a first sprocket 36, two sets of second sprockets 38;

the rotating shaft 23 is fixedly installed on the inner wall of the first chain wheel 36, the driven shaft 42 is fixedly installed on the inner wall of each group of second chain wheels 38, and the two groups of second chain wheels 38 are in transmission connection with the first chain wheel 36 through the chain 37;

the principle is as follows: when the rotating shaft 23 rotates, the two driven shafts 42 are rotated by the first sprocket 36, the two second sprockets 38 and the chain 37.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of these combinations not exhaustive in this specification is merely for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (8)

1. The utility model provides a pressure equipment mechanism of forced air cooling radiator and component, includes bottom plate (10), top middle-end fixed mounting bracing piece (11) of bottom plate (10), top fixed mounting roof (12) of bracing piece (11), its characterized in that still includes:

the press-fitting assembly is used for simultaneously or separately press-fitting the air-cooled radiator or element;

the placing plate (60) is used for placing an air-cooled radiator body or element, and the placing plate (60) is fixedly arranged on two sides of the top of the bottom plate (10).

2. A press-fit mechanism for an air-cooled heat sink and component as claimed in claim 1, wherein said press-fit assembly comprises:

the lifting assembly (50) is used for extruding a body or an element for placing the air-cooled radiator, two ends of the bottom of the top plate (12) are connected with the lifting assembly (50), and a placing plate (60) is arranged right below the lifting assembly (50);

a main driving assembly (20) for driving the lifting assembly (50) to rotate, wherein the main driving assembly (20) is installed on the top middle end of the top plate (12);

driven drive assembly (40), driven drive assembly (40) are all installed at the top both ends of roof (12), and driven drive assembly (40) are connected through transmission assembly (30) with drive lifting unit (50), but driven drive assembly (40) and lifting unit (50) disconnection.

3. The press-fitting mechanism for air-cooled heat sink and element as recited in claim 2, wherein said lifting assembly (50) comprises:

the inner walls of the two ends of the top plate (12) are rotatably connected with the screw rods (51) through bearings;

the nuts (52) are in threaded connection with the screw rods (51) of each group;

two groups of sliding blocks (53), wherein nuts (52) are fixedly arranged on the inner wall of each group of sliding blocks (53);

the supporting shafts (54) are fixedly arranged at two ends of the bottom of each group of sliding blocks (53);

two support shafts (54) are fixedly arranged at two ends of the top of each group of lower pressing plates (55), and a placing plate (60) is arranged right below each group of lower pressing plates (55);

the guide rod (56) is used for avoiding the rotation of the sliding block (53), two sets of guide rods (56) are fixedly mounted at two ends of the bottom of the top plate (12), and each set of guide rods is connected with the inner walls of two ends of the sliding block (53) in a sliding mode and connected with the guide rods (56).

4. A press-fit mechanism of an air-cooled heat sink and component as claimed in claim 2, wherein the main drive assembly (20) comprises:

the middle end of the top plate (12) is fixedly provided with the U-shaped plate (21);

the servo motor (22), the said servo motor (22) is fixedly mounted on top of the U-shaped plate (21);

the rotating shaft (23) is connected to the U-shaped plate (21) in a rotating mode through a bearing, and an output shaft of the servo motor (22) is fixedly connected with the rotating shaft (23) with the same diameter.

5. The press-fit mechanism of an air-cooled radiator and element according to claim 4, wherein the driven driving assembly (40) comprises:

the two ends of the top plate (12) are fixedly provided with the L-shaped plates (41);

the two groups of driven shafts (42), each group of L-shaped plates (41) is rotatably connected with the driven shafts (42) through bearings, and each group of driven shafts (42) is connected with the rotating shaft (23) through a transmission assembly (30);

the bottom of each group of driven shafts (42) is fixedly provided with the air cylinder (43), and the output end of the air cylinder (43) is fixedly provided with the extrusion plate (44) through a piston rod.

6. The press-fit mechanism for the air-cooled radiator and the element is characterized in that a screw rod (51) is arranged right below each group of the extrusion plates (44), and the opposite ends of the extrusion plates (44) and the screw rods (51) are provided with face teeth for improving friction force so as to improve transmission stability.

7. The press-fit mechanism of the air-cooled radiator and the element according to claim 5, wherein the transmission assembly (30) is:

the inner wall of the first belt pulley (31) is fixedly provided with a rotating shaft (23);

two sets of second belt pulley (33), every group the equal fixed mounting driven shaft (42) of inner wall of second belt pulley (33), and two sets of second belt pulley (33) pass through belt (32) transmission with first belt pulley (31) and are connected.

8. The press-fit mechanism of the air-cooled radiator and the element according to claim 5, wherein the transmission assembly (30) is:

the inner wall of the first chain wheel (36) is fixedly provided with a rotating shaft (23);

and the inner wall of each group of second chain wheels (38) is fixedly provided with a driven shaft (42), and the two groups of second chain wheels (38) are in transmission connection with the first chain wheel (36) through a chain (37).

Images