CN113513885A

CN113513885A - Welding flux drying machine

Info

Publication number: CN113513885A
Application number: CN202110720252.1A
Authority: CN
Inventors: 刘杰; 李永刚; 周敬
Original assignee: Chongqing Jodear Power Equipment Co ltd
Current assignee: Chongqing Jodear Power Equipment Co ltd
Priority date: 2021-06-28
Filing date: 2021-06-28
Publication date: 2021-10-19

Abstract

The invention provides a welding flux dryer, which comprises a drying assembly, a drying device and a control device, wherein the drying assembly comprises a drying shell and a movable support piece; the drying shell is provided with an open end, the movable support piece is movably connected to the first open end of the drying shell, and the movable support piece is provided with a working state and an opening state; the heat insulation assembly comprises a heat insulation shell and a movable unit, and the heat insulation shell is movably connected to the drying shell through the movable unit; the heat preservation shell is provided with a second open end, and the second open end and the first open end are oppositely arranged. The dried welding flux directly falls into the heat insulation box for heat insulation, so that the risk of moisture of the surrounding environment caused by multiple transfer contact in the midway is avoided, the workload of operators is reduced, and the site space is saved.

Description

Welding flux drying machine

Technical Field

The invention relates to the technical field of welding flux equipment, in particular to a welding flux dryer.

Background

The flux is a granular welding material which can be melted to form slag and gas during welding, and has a protective and metallurgical effect on the molten pool. During welding, the material can be melted to form slag and gas, and the slag and gas can protect and metallurgically treat molten metal.

In the related art, the dried flux needs to be transferred from the dryer into the heat preservation box and stored at the temperature of 100-.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a welding flux dryer, which aims to solve the technical problem that the welding flux is easy to damp after being transferred for many times before being used in the related art.

The invention provides a welding flux dryer, comprising:

the drying assembly comprises a drying shell and a movable support piece; the drying shell is provided with a first opening end, the movable support piece is movably connected to the first opening end of the drying shell and is provided with a working state and an opening state, when in the working state, the movable support piece seals the first opening end, and one side of the movable support piece, which is close to the drying shell, and the inner wall of the drying shell enclose to form a drying chamber for containing drying welding flux;

the heat insulation assembly comprises a heat insulation shell and a movable unit, and the heat insulation shell is movably connected to the drying shell through the movable unit; the heat-insulating shell is provided with a second open end, and the second open end and the first open end are oppositely arranged; when the drying device is in the working state, one side of the movable supporting piece, which is far away from the drying shell, and the inner wall of the heat-insulating shell enclose to form a heat-insulating chamber; in the open state, the drying chamber is communicated with the heat preservation chamber.

Optionally, the drying machine further comprises a drying machine box body and a feeding assembly, the drying assembly and the heat preservation assembly are arranged in the drying machine box body, and the feeding assembly is connected with the top of the drying machine box body and communicated with the drying shell body.

Optionally, the heat preservation assembly further comprises a heating element, a pulley, a push-pull rod, a first driving member and a partition plate; the heating element is arranged at the bottom in the heat-insulating shell, the first driving piece is arranged on one side in the heat-insulating shell, the first driving piece is electrically connected with the heating element, the partition board separates the heating element from the first driving piece to form a closed space, the push-pull rod is arranged on the outer wall of the heat-insulating shell close to the first driving piece, and the pulley is fixedly connected to the bottom end of the heat-insulating shell.

Optionally, the movable unit includes a first chute and a second chute, the first chute is disposed on two sides of the bottom of the drying casing, two sides of the heat-insulating casing are matched with the first chute, the second chute is disposed on the bottom end of the drying machine casing, and the second chute is matched with the pulley.

Optionally, the drying assembly further includes a second driving element and a working element, one end of the working element is connected to one side of the outer wall of the drying casing, which is close to the movable supporting element, and the other end of the working element is connected to one side of the movable supporting element, which is close to the second open end; the second driving piece is close to the heat preservation shell and arranged in the dryer box body, and the second driving piece is electrically connected with the workpiece.

Optionally, the feeding subassembly includes shock dynamo, shock-absorbing rod, connecting rod, first screening layer, second screening layer, shock dynamo passes through the shock-absorbing rod is located one side at drying-machine box top, first screening layer passes through the shock-absorbing rod is located the upper end of drying-machine box, the second screening layer passes through the shock-absorbing rod is located the top on first screening layer, one side of shock dynamo passes through the connecting rod respectively with first screening layer and second screening layer fixed connection.

Optionally, the feeding subassembly still includes movable filter screen, change mouth has been seted up respectively to first screening layer with one side of second screening layer, movable filter screen passes through respectively change mouthful sliding connection in first screening layer with the second screening layer.

Optionally, the dryer box further comprises an exhaust duct, and the exhaust duct passes through the dryer box and communicates with the drying housing.

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

will the welding flux after drying in the drying casing directly falls into the heat preservation casing keeps warm, has avoided midway to shift the risk that contacts the surrounding environment and wets many times, has reduced operating personnel's work load simultaneously, has saved the place space.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view of the heat retention assembly of the present invention;

FIG. 4 is a schematic diagram of the right view structure of the present invention;

fig. 5 is an enlarged schematic view of a portion a of fig. 2.

The reference numbers illustrate:

1. a dryer box body; 101. drying the shell; 1011. a temperature detector; 102. a first chute; 103. a second chute; 104. operating a control panel; 1041. a liquid crystal display; 1043. an operation button; 105. a workpiece; 106. an electromagnetic valve; 107. a second driving member; 108. a movable support; 109. an exhaust gas pipe; 110. an exhaust valve; 111. a heat preservation port; 2. a feed assembly; 201. vibrating a motor; 202. a shock-absorbing lever; 203. a connecting rod; 204. a first screening layer; 205. a second screening layer; 206. a movable filter screen; 3. a heat-insulating shell; 301. a push-pull rod; 302. a pulley; 303. a heating element; 304. a first driving member; 305. a partition panel.

The implementation, functional features and advantages of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

In order to make the objects, technical solutions and beneficial effects of the present invention more clearly apparent, the technical solutions of the present invention are further described below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1 to 5, the present invention provides a flux dryer including:

a drying assembly including a drying casing 101 and a movable support 108; the drying shell 101 has a first open end, the movable support 108 is movably connected to the first open end of the drying shell 101, the movable support 108 has a working state and an open state, in the working state, the movable support 108 seals the first open end, and one side of the movable support 108 close to the drying shell 101 and the inner wall of the drying shell 101 enclose to form a drying chamber for containing drying flux;

the heat preservation assembly comprises a heat preservation shell 3 and a movable unit, wherein the heat preservation shell 3 is movably connected to the drying shell 101 through the movable unit; the heat-insulating shell 3 is provided with a second open end, and the second open end is opposite to the first open end; in the working state, one side of the movable support 108 far away from the drying casing 101 and the inner wall of the heat-insulating casing 3 enclose to form a heat-insulating chamber; in the open state, the drying chamber is communicated with the heat preservation chamber.

In this embodiment, the flux to be dried falls into the heat-insulating housing 3 below via the movable supporting member 108 after being dried in the drying housing 101, so that the number of times of contact between the dried flux and the outside is reduced, the flux is prevented from being affected with damp, and the heat-insulating housing 3 further insulates the dried flux.

Optionally, the dryer further comprises a dryer box body 1 and a feeding assembly 2, the drying assembly and the heat preservation assembly are arranged in the dryer box body 1, and the feeding assembly 2 is connected to the top of the dryer box body and communicated with the drying shell 101.

In this embodiment, a heat preservation port 111 is formed in one side of the dryer box, and the heat preservation assembly is slidably connected with the drying assembly through the heat preservation port 111; the front side of the dryer box body is also provided with an operation control panel 104 and a movable door capable of being opened or closed, wherein the operation control panel 104 comprises a PCB (printed circuit board), a liquid crystal display 1041 and an operation button 1043; 1043; preferably, a temperature detector 1011 is arranged in the drying casing 101, and the temperature detector 1011 is connected to the liquid crystal display 1041 and is used for feeding back a temperature value in the drying casing 101.

Optionally, the thermal insulation assembly further comprises a heating element 303, a pulley 302, a push-pull rod 301, a first driving member 304 and a partition plate 305; the heating element 303 is disposed at the bottom of the heat preservation housing 3, the first driving member 304 is disposed at one side of the heat preservation housing 3, the first driving member 304 is electrically connected to the heating element 303, the partition plate 305 partitions the heating element 303 and the first driving member 304 to form a closed space, the push-pull rod 301 is disposed on the outer wall of the heat preservation housing 3 close to the first driving member 304, and the pulley 302 is fixedly connected to the bottom end of the heat preservation housing 3.

In this embodiment, the heating element 303 is preferably a heating pipe, and may be arranged side by side or across at the bottom of the thermal insulation shell 3; the pulley 302 and the push-pull rod 301 facilitate moving the heat preservation shell 3, facilitate quickly transferring to a processing site, and simultaneously realize continuous heat preservation in the moving process.

Optionally, the movable unit includes a first chute 102 and a second chute 103, the first chute 102 is disposed on two sides of the bottom of the drying casing 101, two sides of the heat preservation casing 3 are matched with the first chute 102, the second chute 103 is disposed at the bottom end in the drying machine box, and the second chute 103 is matched with the pulley 302.

In this embodiment, the first sliding groove 102 and the second sliding groove 103 are used for positioning and facilitating the sliding in and out of the heat insulation assembly, and meanwhile, two sides of the heat insulation housing 3 slide in the first sliding groove 102, when the movable supporting member 108 is closed in a working state, the heat insulation housing 3 forms a closed heat insulation chamber, so that a heat insulation effect is better achieved.

Optionally, the drying assembly further comprises a second driving member 107 and a working member 105, one end of the working member 105 is connected to one side of the outer wall of the drying casing 101 close to the movable support 108, and the other end of the working member 105 is connected to one side of the movable support 108 close to the second open end; the second driving part 107 is arranged in the drying machine box body close to the heat preservation shell 3, and the second driving part 107 is electrically connected with the workpiece 105.

In this embodiment, the working member 105 is preferably a hydraulic telescopic rod or an air cylinder, the working member 105 is electrically connected to a PCB board in the operation control panel 104, the operation control panel 104 controls the drying casing 101 to perform drying at fixed time and fixed temperature, and a timing module in the operation control panel 104 sends a signal to an electromagnetic valve 106, and the electromagnetic valve 106 disconnects different magnetic coils to control the hydraulic telescopic rod or the air cylinder to open and close the movable supporting member 108.

Optionally, feeding component 2 includes shock dynamo 201, bumper bar 202, connecting rod 203, first screening layer 204, second screening layer 205, shock dynamo 201 passes through bumper bar 202 is located one side at drying-machine box 1 top, first screening layer 204 passes through bumper bar 202 is located the upper end of drying-machine box 1, second screening layer 205 passes through bumper bar 202 is located the top of first screening layer 204, one side of shock dynamo 201 passes through connecting rod 203 respectively with first screening layer 204 and second screening layer 205 fixed connection.

In this embodiment, first screening layer 204 and second screening layer 205 are used for screening the flux of different granularities, through shock dynamo 1 drives connecting rod 203, first screening layer 204 with second screening layer 205 shakes, and the granule that accords with the size falls into the stoving cavity, and the flux that exceeds the size then stays first screening layer 204 with second screening layer 205 has alleviateed the work of manual screening.

Optionally, the feeding assembly 2 further includes a movable filter screen 206, replacement openings are respectively opened at one side of the first screening layer 204 and one side of the second screening layer 205, and the movable filter screen 206 is slidably connected to the first screening layer 204 and the second screening layer 205 through the replacement openings, respectively.

In this embodiment, the movable filter screen 206 is replaced through the replacement port, and is used for replacing commonly used filter screens with the granularity of 2.5-0.45mm (8-40 meshes) and 1.43-0.28mm (10-60 meshes) according to requirements.

Optionally, the dryer box 1 further includes an exhaust duct 109, and the exhaust duct 109 penetrates through the dryer box 1 and communicates with the drying casing 101.

In this embodiment, a valve, preferably an exhaust valve 110, is disposed on the exhaust pipe 109, and the exhaust valve 110 is electrically connected to the operation control panel 104 for collecting and treating the exhaust gas uniformly.

Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.

Claims

1. A flux dryer, comprising:

2. The flux dryer of claim 1, further comprising a dryer housing and a feed assembly, said drying assembly and said insulating assembly being disposed within said dryer housing, said feed assembly being connected to a top of said dryer housing and communicating with said drying enclosure.

3. The flux dryer of claim 2 wherein said thermal subassembly further comprises a heating element, a pulley, a push-pull rod, a first drive member, and a partition plate; the heating element is arranged at the bottom in the heat-insulating shell, the first driving piece is arranged on one side in the heat-insulating shell, the first driving piece is electrically connected with the heating element, the partition board separates the heating element from the first driving piece to form a closed space, the push-pull rod is arranged on the outer wall of the heat-insulating shell close to the first driving piece, and the pulley is fixedly connected to the bottom end of the heat-insulating shell.

4. The welding flux dryer as claimed in claim 3, wherein said movable unit includes a first sliding slot and a second sliding slot, said first sliding slot is disposed on two sides of the bottom of said drying casing, two sides of said heat-insulating casing are matched with said first sliding slot, said second sliding slot is disposed at the bottom end of said drying casing, said second sliding slot is matched with said pulley.

5. The flux dryer of claim 4, wherein said drying assembly further comprises a second driving member and a working member, one end of said working member is connected to a side of said outer wall of said drying casing adjacent to said movable support, and the other end of said working member is connected to a side of said movable support adjacent to said second open end; the second driving piece is close to the heat preservation shell and arranged in the dryer box body, and the second driving piece is electrically connected with the workpiece.

6. The welding flux dryer as claimed in claim 5, wherein said feeding assembly comprises a vibration motor, a damper rod, a connecting rod, a first screening layer and a second screening layer, said vibration motor is disposed at one side of the top of said dryer casing through said damper rod, said first screening layer is disposed at the upper end of said dryer casing through said damper rod, said second screening layer is disposed at the top of said first screening layer through said damper rod, and one side of said vibration motor is fixedly connected with said first screening layer and said second screening layer through said connecting rod, respectively.

7. The flux dryer of claim 6, wherein said feeding assembly further comprises a movable screen, one side of said first screening layer and one side of said second screening layer are respectively opened with a replacement port, and said movable screen is slidably connected to said first screening layer and said second screening layer through said replacement ports, respectively.

8. The flux dryer of claim 7 wherein said dryer housing further includes an exhaust duct passing through said dryer housing in communication with said drying enclosure.