CN216801025U - Nickel white copper strip high temperature oxidation resistance processing apparatus - Google Patents

Abstract

The utility model discloses a nickel-copper strip high-temperature oxidation resistant treatment device, which relates to the technical field of oxidation treatment and comprises the following steps: a base; the supporting plate is arranged at the top end of one end of the base; an adjustment mechanism; and a support mechanism. According to the utility model, by arranging the adjusting mechanism, the mechanism can realize sleeve joint of nickel white copper strips with different widths, the nickel white copper strips are sleeved with the movable pulling plate, at the moment, the first clamping block is extruded into the movable pulling plate, the second spring is extruded, the nickel white copper strips are sleeved with the supporting shaft, at the moment, the nickel white copper strips are blocked by the partition baffle, the movable pulling plate is pulled to drive the movable pulling rod to extend to the outer wall of one end of the supporting shaft, at the moment, the movable baffle is driven by the movable pulling rod to extrude the first spring, then the second spring pushes the first clamping block to reset through pressure rebounding, at the moment, the first spring pushes the movable baffle through pressure rebounding, so that the first clamping block limits and fixes the nickel white copper strips with different widths, and therefore, the nickel white copper strips with different widths can be conveniently fixed.

Description

Nickel white copper strip high temperature oxidation resistance processing apparatus

Technical Field

The utility model relates to the technical field of oxidation treatment, in particular to a nickel-copper strip high-temperature oxidation resistant treatment device.

Background

The white copper strip is a copper alloy with nickel as a main alloy element, and is correspondingly called a zinc white copper strip, a manganese white copper strip and an aluminum white copper bar strip, wherein a third element such as zinc, manganese, aluminum and the like is added on the basis of the copper-nickel alloy, and the copper-nickel alloy has good corrosion resistance, moderate strength and high plasticity and can be processed by hot and cold pressing.

According to the publication number 'CN 212703202U', the device is a 'high-temperature oxidation resistant treatment device for the zinc white copper strip', comprises a workbench, the utility model has reasonable structure, the fixed rod is extruded to lead the extrusion spring to move and generate elastic deformation, so that the fixed rod moves into the movable groove of the telescopic rod, then the copper belt wheel is put in, then the telescopic rod is pulled outwards to drive the return spring to generate elastic deformation, when the telescopic rod moves out of the copper belt wheel, the extrusion spring which generates elastic deformation drives the fixed rod to reset, the telescopic rod is loosened, the reset spring which generates elastic deformation drives the telescopic rod to reset to push against the copper belt wheel, thereby fixing the copper belt wheel with different widths, and then can wash the copper strips of different width, make the brush thoroughly wash the copper strips simultaneously.

Above-mentioned structure makes the brush carry out rinse thoroughly to the copper strips to very big improvement to the abluent efficiency and effect of nickel cupronickel belt, however, above-mentioned patent is in the use, and its structure can't carry out spacing fixed to the copper strips of different width, simultaneously because nickel cupronickel belt itself is heavier, long-term use can lead to the phenomenon that equipment such as dwang took place to damage, is unfavorable for the use.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a nickel-copper strip high-temperature oxidation resistance treatment device to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme:

the utility model provides a nickel white copper strips anti high temperature oxidation processing apparatus, includes:

a base;

the supporting plate is arranged at the top end of one end of the base;

the adjusting mechanism is provided with a first motor, is arranged at one end of the supporting plate far away from the base, penetrates through the supporting plate to the upper part of the base and is used for sleeving and supporting the nickel-copper strips with different widths;

the supporting mechanism is installed at one end of the base, located under the first motor and penetrating into the base, and is used for bearing the nickel-copper strip.

As a still further scheme of the utility model: the adjusting mechanism comprises a first motor, a separation baffle, a first spring, a support shaft, a movable baffle, a movable pull rod, a first fixture block, a movable pull plate and a second spring, the first motor is arranged at one end of the support plate far away from the base, the support shaft is fixed at the output end of the first motor, is positioned at one end of the support plate far away from the first motor and is positioned above the base, the separation baffle is arranged at one end of the support plate far away from the first motor and is fixedly sleeved with the support shaft, the movable pull plate is arranged at one end of the support shaft far away from the support plate, the first fixture block is arranged at the top end of the movable pull plate and penetrates into the movable pull plate, the second spring is arranged at the lower surface of the first fixture block and is positioned inside the movable pull plate, the movable pull rod is fixed at one end of the movable pull plate close to the support shaft and penetrates into the support shaft, the movable baffle is fixed at one end, far away from the movable pull plate, of the movable pull rod and located inside the supporting shaft, and the first spring is arranged at one end, close to the movable pull plate, of the movable baffle and is in sleeve joint with the movable pull rod.

As a still further scheme of the utility model: the supporting mechanism comprises a second motor, a linkage rotating shaft, a movable sliding block, a threaded rod, a supporting turning plate, a third spring and a second clamping block, the second motor is arranged at one end of the base, and is positioned under the first motor, the linkage rotating shaft is fixed at the output end of the second motor and penetrates into the base, the threaded rod is fixed at one end of the linkage rotating shaft far away from the second motor, the movable sliding block is arranged at one end of the linkage rotating shaft far away from the second motor and is mutually sleeved with the threaded rod, the supporting turning plate is arranged at the top end of the movable sliding block and is positioned at one end of the movable pulling plate far away from the supporting shaft, the second clamping block is arranged at the top end of one side of the supporting turning plate, and the third spring is arranged on the lower surface of the second clamping block and is positioned in the supporting turning plate.

As a still further scheme of the utility model: the output end of the first motor is rotatably connected with the supporting plate through a bearing, and a limiting sliding groove matched with the outer wall of the supporting shaft is arranged at the joint of the supporting shaft, the movable baffle and the movable pull rod.

As a still further scheme of the utility model: one end of the movable pulling plate, which is positioned at the supporting turning plate, is provided with a bearing block which is sleeved with the movable pulling plate, and a position where the first clamping block is connected with the second spring is provided with a limit baffle.

As a still further scheme of the utility model: the supporting turning plate is rotatably connected with the movable sliding block through a hinge, and a movable sliding groove matched with the outer wall of the base is arranged at the connecting position of the base and the movable sliding block.

As a still further scheme of the utility model: the position where the movable sliding block is connected with the threaded rod is provided with a threaded groove matched with the outer wall of the movable sliding block, the position where the second clamping block is connected with the third spring is provided with a limiting baffle matched with the outer wall of the second clamping block, and the output end of the second motor is rotatably connected with the base through a bearing.

Compared with the prior art, the utility model has the beneficial effects that:

1. by arranging the adjusting mechanism, the mechanism can realize the sleeve joint of nickel white copper strips with different widths, the nickel white copper strips are sleeved with the movable pulling plate, at the moment, the first clamping block is extruded into the movable pulling plate, the second spring is extruded, the nickel white copper strips are sleeved with the supporting shaft, the nickel white copper strips are blocked by the partition baffle, the movable pulling plate is pulled to drive the movable pulling rod to extend to the outer wall of one end of the supporting shaft, the movable baffle is driven by the movable pulling rod to extrude the first spring, then the second spring pushes the first clamping block to reset through pressure rebound, at the moment, the first spring pushes the movable baffle through pressure rebound, so that the first clamping block limits and fixes the nickel white copper strips, and the nickel white copper strips with different widths are conveniently fixed;

2. through setting up supporting mechanism, this mechanism can realize effectively supporting the nickel copper-nickel strap, drive the linkage pivot through starting the second motor, make the threaded rod rotate, it drives down at the rotatory drive of threaded rod to remove the slider this moment, it removes the board below the one end that removes the arm-tie to drive to support to turn over, then support through the hinge upset and turn over the board and cup joint each other with the bearing block, the second fixture block passes through the extrusion this moment, get into the inside that supports the board that turns over, and extrude the third spring, then the third spring is through the pressure bounce-back promotion second fixture block and resets, thereby the realization is supported the nickel copper-nickel strap, effectively avoid the back shaft to take place cracked phenomenon after long-time use.

Drawings

FIG. 1 is a schematic structural diagram of a nickel-copper strip high-temperature oxidation resistance processing device;

FIG. 2 is a schematic cross-sectional view of an adjusting mechanism and a supporting mechanism of a nickel-copper strip high-temperature oxidation resistance processing device;

fig. 3 is a schematic view of a part a of a nickel white copper strip high temperature oxidation resistance processing device.

In the figure: 1. a base; 2. an adjustment mechanism; 201. a first motor; 202. a baffle plate; 203. a first spring; 204. a support shaft; 205. moving the baffle; 206. moving the pull rod; 207. a first clamping block; 208. moving the pulling plate; 209. a second spring; 3. a support mechanism; 301. a second motor; 302. a linkage rotating shaft; 303. moving the slide block; 304. a threaded rod; 305. supporting the turning plate; 306. a third spring; 307. a second fixture block; 4. and a support plate.

Detailed Description

Referring to fig. 1 to 3, in an embodiment of the present invention, an apparatus for anti-high temperature oxidation treatment of a nickel-copper strip includes:

a base 1;

the supporting plate 4 is arranged at the top end of one end of the base 1;

the adjusting mechanism 2 is provided with a first motor 201, and the adjusting mechanism 2 is arranged at one end of the supporting plate 4 far away from the base 1, penetrates through the supporting plate 4 to the upper part of the base 1, and is used for sleeving and supporting nickel-copper strips with different widths;

the supporting mechanism 3 is installed at one end of the base 1, is located under the first motor 201, penetrates through the base 1, and is used for bearing the nickel-copper alloy belt.

This kind of anti high temperature oxidation processing apparatus of nickel copper strips through cup jointing nickel copper strip and adjustment mechanism 2, is convenient for make the nickel copper strip unsettled in the one end of backup pad 4 to the realization is carried out spacing the cup jointing to the nickel copper strip of different width, supports adjustment mechanism 2 through supporting mechanism 3 simultaneously, thereby effectively supports the nickel copper strip, effectively avoids adjustment mechanism 2 to take place to damage.

In FIGS. 1 to 3: the adjusting mechanism 2 comprises a first motor 201, a baffle plate 202, a first spring 203, a supporting shaft 204, a movable baffle plate 205, a movable pull rod 206, a first fixture block 207, a movable pull plate 208 and a second spring 209, wherein the first motor 201 is installed at one end of the supporting plate 4 far away from the base 1, the supporting shaft 204 is fixed at the output end of the first motor 201, is positioned at one end of the supporting plate 4 far away from the first motor 201 and is positioned above the base 1, the baffle plate 202 is arranged at one end of the supporting plate 4 far away from the first motor 201 and is fixedly sleeved with the supporting shaft 204, the movable pull plate 208 is arranged at one end of the supporting shaft 204 far away from the supporting plate 4, the first fixture block 207 is arranged at the top end of the movable pull plate 208 and penetrates into the movable pull plate 208, the second spring 209 is arranged at the lower surface of the first fixture block 207 and is positioned inside the movable pull plate 208, the movable pull rod 206 is fixed at one end of the movable pull plate 208 near the supporting shaft 204, and penetrates into the inside of the supporting shaft 204, the movable baffle 205 is fixed at one end of the movable pull rod 206 far away from the movable pull plate 208 and is positioned inside the supporting shaft 204, and the first spring 203 is arranged at one end of the movable baffle 205 close to the movable pull plate 208 and is sleeved with the movable pull rod 206.

The nickel-copper white strip high-temperature oxidation resistance treatment device comprises a nickel-copper white strip and a movable pulling plate 208 which are sleeved, wherein a first clamping block 207 is lowered into the movable pulling plate 208 through extrusion, a second spring 209 is extruded through a limiting baffle, the nickel-copper white strip is sleeved with a supporting shaft 204, the nickel-copper white strip is blocked through a separation baffle 202, the movable pulling plate 208 is pulled to drive a movable pulling rod 206 to extend towards the outer wall of one end of the supporting shaft 204, the movable baffle 205 is driven by the movable pulling rod 206 to slide in the supporting shaft 204 and extrude a first spring 203, then the second spring 209 pushes the first clamping block 207 to reset through compression rebound, the first spring 203 pushes the movable pulling plate 205 to drive the movable pulling rod 206 through compression rebound so that the movable pulling plate 208 drives the first clamping block 207 to limit and fix the nickel-copper white strip, thereby conveniently fixing the nickel-copper-nickel strips with different widths.

In FIGS. 1 to 3: the supporting mechanism 3 comprises a second motor 301, a linkage rotating shaft 302, a moving slide block 303, a threaded rod 304, a supporting turning plate 305, a third spring 306 and a second fixture block 307, the second motor 301 is installed at one end of the base 1 and is positioned right below the first motor 201, the linkage rotating shaft 302 is fixed at the output end of the second motor 301 and penetrates into the base 1, the threaded rod 304 is fixed at one end of the linkage rotating shaft 302 far away from the second motor 301, the moving slide block 303 is arranged at one end of the linkage rotating shaft 302 far away from the second motor 301, is sleeved with the threaded rod 304 and penetrates to the top end of the base 1, the supporting turning plate 305 is installed at the top end of the moving slide block 303 and is positioned at one end of the moving pull plate 208 far away from the supporting shaft 204, the second fixture block 307 is arranged at the top end of one side of the supporting turning plate 305 and penetrates into the inside of the supporting turning plate, the third spring 306 is arranged at the lower surface of the second fixture block 307, and is located inside the support flap 305.

This kind of anti high temperature oxidation processing apparatus of nickel white copper strip, it makes threaded rod 304 rotate in base 1's inside to drive linkage pivot 302 through starting second motor 301, it drives under the rotatory drive of threaded rod 304 through the thread groove to remove slider 303 this moment, it drives and supports board 305 and remove to the one end below that removes arm-tie 208 to drive, then support board 305 and bearing block cup joint each other through the hinge upset, second fixture block 307 is under the extrusion of bearing block this moment, get into and support the inside of turning board 305, and extrude third spring 306 through limit baffle, then third spring 306 promotes second fixture block 307 through the pressurized bounce-back and resets, thereby make through the bearing block to support board 305 and support the nickel white copper strip, effectively avoid back shaft 204 to take place cracked phenomenon after long-time uses.

In FIGS. 1 to 3: the output end of the first motor 201 is rotatably connected with the support plate 4 through a bearing, and a limiting sliding groove matched with the outer wall of the support shaft 204 is arranged at the connecting position of the support shaft 204, the movable baffle 205 and the movable pull rod 206.

According to the high-temperature oxidation resistant treatment device for the nickel-copper strip, the movable baffle 205 and the movable pull rod 206 are enabled to slide in the supporting shaft 204 in a limiting manner through the limiting sliding grooves.

In FIGS. 1 to 3: one end of the movable pulling plate 208, which is located at the supporting turning plate 305, is provided with a bearing block which is sleeved with the movable pulling plate, and a position where the first clamping block 207 is connected with the second spring 209 is provided with a limit baffle.

According to the high-temperature oxidation resistant treatment device for the nickel-copper strip, the movable pull plate 208 drives the movable pull rod 206 and the support shaft 204 to transversely support the nickel-copper strip through the support turning plate 305 through the bearing block.

In FIGS. 2 to 3: the supporting turning plate 305 is rotatably connected with the movable sliding block 303 through a hinge, and a movable sliding groove matched with the outer wall of the base 1 is arranged at the connecting position of the base and the movable sliding block 303.

This kind of anti high temperature oxidation processing apparatus of nickel copper strip makes the slider 303 that removes carry out spacing slip in the inside of base 1 through removing the spout.

In FIGS. 2 to 3: a threaded groove matched with the outer wall of the threaded rod 304 is formed in the joint of the movable sliding block 303 and the threaded rod 304, a limit baffle matched with the outer wall of the second fixture block 307 is arranged in the joint of the third spring 306, and the output end of the second motor 301 is rotatably connected with the base 1 through a bearing.

According to the nickel-copper strip high-temperature oxidation resistance treatment device, the movable sliding block 303 is driven by the rotation of the threaded rod 304 through the limit baffle to drive the support turning plate 305 to move to the position below one end of the movable pulling plate 208.

The working principle of the utility model is as follows: when in use, the nickel white copper strip is sleeved with the movable pulling plate 208, at the moment, the first fixture block 207 is lowered to the inside of the movable pulling plate 208 through extrusion, the second spring 209 is extruded through the limiting baffle, the nickel white copper strip is sleeved with the supporting shaft 204, at the moment, the nickel white copper strip is blocked through the separation baffle 202, the movable pulling plate 208 is pulled to drive the movable pulling rod 206 to extend towards the outer wall of one end of the supporting shaft 204, at the moment, the movable baffle 205 is driven by the movable pulling rod 206 to slide in the inside of the supporting shaft 204 and extrude the first spring 203, then the second spring 209 pushes the first fixture block 207 to reset through compression and rebound, at the moment, the first spring 203 pushes the movable baffle 205 to drive the movable pulling plate 206 through compression and rebound so that the movable pulling plate 208 drives the first fixture block 207 to limit and fix the nickel white copper strip, thereby conveniently fixing the nickel white copper strips with different widths, meanwhile, the second motor 301 is started to drive the linkage rotating shaft 302 to enable the threaded rod 304 to rotate in the base 1, at the moment, the movable sliding block 303 drives the support turning plate 305 to move below one end of the movable pulling plate 208 through the threaded groove under the driving of the rotation of the threaded rod 304, then the support turning plate 305 and the bearing block are mutually sleeved through the hinge, at the moment, the second fixture block 307 enters the inside of the support turning plate 305 under the extrusion of the bearing block and extrudes the third spring 306 through the limit baffle, then the third spring 306 pushes the second fixture block 307 to reset through the compression and rebound, so that the support turning plate 305 supports the nickel-copper alloy strip through the bearing block, the phenomenon that the support shaft 204 is broken after long-time use is effectively avoided, then, the first motor 201 is started to drive the baffle plate 202 and the supporting shaft 204 to enable the nickel cupronickel strip to rotate, so that the nickel cupronickel strip is subjected to high-temperature oxidation resistance treatment conveniently.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present invention, and the technical solutions and the utility model concepts of the present invention are equivalent to or changed within the scope of the present invention.

Claims (7)

1. The utility model provides a nickel white copper strips anti high temperature oxidation processing apparatus which characterized in that includes:

a base (1);

the supporting plate (4) is arranged at the top end of one end of the base (1);

the adjusting mechanism (2) is provided with a first motor (201), the adjusting mechanism (2) is installed at one end, far away from the base (1), of the supporting plate (4), penetrates through the supporting plate (4) to the upper side of the base (1), and is used for sleeving and supporting nickel-copper strips with different widths;

and the supporting mechanism (3) is installed at one end of the base (1), is positioned under the first motor (201), penetrates through the base (1), and is used for bearing the nickel-copper strip.

2. The nickel-copper strip high-temperature oxidation resistance treatment device according to claim 1, wherein the adjusting mechanism (2) comprises a first motor (201), a baffle plate (202), a first spring (203), a support shaft (204), a movable baffle plate (205), a movable pull rod (206), a first fixture block (207), a movable pull plate (208) and a second spring (209), the first motor (201) is installed at one end of the support plate (4) far away from the base (1), the support shaft (204) is fixed at the output end of the first motor (201), is located at one end of the support plate (4) far away from the first motor (201), and is located above the base (1), the baffle plate (202) is arranged at one end of the support plate (4) far away from the first motor (201) and is fixedly sleeved with the support shaft (204), the movable pull plate (208) is arranged at one end of the support shaft (204) far away from the support plate (4), the first fixture block (207) is arranged at the top end of the movable pull plate (208) and penetrates through the movable pull plate (208), the second spring (209) is arranged on the lower surface of the first fixture block (207) and located inside the movable pull plate (208), the movable pull rod (206) is fixed at one end, close to the support shaft (204), of the movable pull plate (208) and penetrates through the support shaft (204), the movable baffle (205) is fixed at one end, far away from the movable pull plate (208), of the movable pull rod (206) and located inside the support shaft (204), the first spring (203) is arranged at one end, close to the movable pull plate (208), of the movable baffle (205) and is mutually sleeved with the movable pull rod (206).

3. The nickel-copper strip high-temperature oxidation resistance processing device according to claim 2, wherein the supporting mechanism (3) comprises a second motor (301), a linkage rotating shaft (302), a moving sliding block (303), a threaded rod (304), a supporting turning plate (305), a third spring (306) and a second clamping block (307), the second motor (301) is installed at one end of the base (1) and located right below the first motor (201), the linkage rotating shaft (302) is fixed at the output end of the second motor (301) and penetrates into the base (1), the threaded rod (304) is fixed at one end of the linkage rotating shaft (302) far away from the second motor (301), the moving sliding block (303) is arranged at one end of the linkage rotating shaft (302) far away from the second motor (301), is mutually sleeved with the threaded rod (304) and penetrates to the top end of the base (1), the supporting turning plate (305) is arranged at the top end of the movable sliding block (303) and is located at one end, away from the supporting shaft (204), of the movable pulling plate (208), the second clamping block (307) is arranged at the top end of one side of the supporting turning plate (305) and penetrates into the supporting turning plate (305), and the third spring (306) is arranged on the lower surface of the second clamping block (307) and is located inside the supporting turning plate (305).

4. The nickel-copper strip high-temperature oxidation treatment device as claimed in claim 2, wherein the output end of the first motor (201) is rotatably connected with the support plate (4) through a bearing, and a position where the support shaft (204) is connected with the movable baffle (205) and the movable pull rod (206) is provided with a limit sliding groove matched with the outer wall of the support shaft.

5. The nickel-copper strip high-temperature oxidation treatment device according to claim 2, wherein a bearing block sleeved with the movable pulling plate (208) is arranged at one end of the movable pulling plate (208) located at the supporting turning plate (305), and a limit baffle is arranged at a position where the first clamping block (207) and the second spring (209) are connected.

6. The nickel-copper strip high-temperature oxidation treatment device according to claim 3, wherein the support turning plate (305) is rotatably connected with the movable sliding block (303) through a hinge, and a movable sliding groove matched with the outer wall of the base (1) is formed in the position where the base is connected with the movable sliding block (303).

7. The nickel-copper strip high-temperature oxidation resistance processing device as claimed in claim 3, wherein a threaded groove matched with the outer wall of the threaded rod (304) is formed in the position where the movable sliding block (303) is connected with the threaded rod, a limit baffle matched with the outer wall of the second clamping block (307) is arranged in the position where the second clamping block (307) is connected with the third spring (306), and the output end of the second motor (301) is rotatably connected with the base (1) through a bearing.

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