CN219378970U - Rotary powder sintering furnace equipment with pressure - Google Patents

Abstract

The utility model relates to the technical field of metallurgy, in particular to rotary powder sintering furnace equipment with pressure, which comprises a sintering furnace main body, wherein a treatment tank is arranged on one side of the sintering furnace main body, a flow guide pipe for conveying gas is arranged between the sintering furnace main body and the treatment tank, a recovery mechanism for recovering gas heat and purifying gas is arranged in the treatment tank, a cleaning mechanism for cleaning impurities in the treatment tank is also arranged on the sintering furnace main body, the recovery mechanism comprises a heat conducting sleeve which is fixedly connected in the treatment tank and is connected with the flow guide pipe and is commonly used for conducting heat, a water storage cavity for storing liquid is arranged in the treatment tank, a plurality of filter screens for filtering gas are arranged in the heat conducting sleeve, an air outlet pipe for leading out the gas is fixedly connected between a sealing plate and a similar filter screen, the heat in the gas is transferred to water for the water storage cavity by the heat sleeve, the energy in the gas can be recycled, and the impurities in the gas can be filtered by the arrangement of the plurality of filter screens.

Description

Rotary powder sintering furnace equipment with pressure

Technical Field

The utility model relates to the technical field of gold treatment, in particular to rotary powder sintering furnace equipment with pressure.

Background

The powder metallurgy sintering furnace is a heat treatment equipment for forming and sintering metal or alloy parts by using metal powder (or a mixture of metal powder and non-metal powder) as a raw material, and is mainly used for iron-based, copper-based and other related powder metallurgy products formed by pressing, and the type of sintering furnace is mainly an electric furnace.

In the process of processing powder metal, the sintering furnace can generate a large amount of harmful gas, direct emission can cause harm to the environment and human beings, the existing powder sintering furnace carries out certain purification treatment on the gas and discharges, but the gas contains a large amount of heat, the direct discharge can not recycle the heat in the gas, and the waste of resources can be caused.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides rotary powder sintering furnace equipment with pressure, which has the advantage of recovering energy in gas and solves the problem of energy waste caused by direct gas discharge.

In order to solve the technical problems, the utility model provides the following technical scheme:

the utility model provides a rotary powder sintering furnace equipment with pressure, includes the sintering furnace main part, sintering furnace main part one side is provided with the treatment tank, is provided with the honeycomb duct that is used for carrying gas between sintering furnace main part and the treatment tank, is provided with the recovery mechanism that is used for retrieving gaseous heat and clean gas in the treatment tank, still is provided with the clearance mechanism that is used for clearing up the interior impurity of treatment tank in the sintering furnace main part, recovery mechanism is including the rigid coupling in the treatment tank and link to each other the heat conduction cover that is commonly used for heat conduction with the honeycomb duct, and the treatment tank embeds has the water storage chamber that is used for storing liquid, is provided with a plurality of filter screens that are used for filtering gas in the heat conduction cover, and the one end rigid coupling that the honeycomb duct was kept away from to the heat conduction cover has the closing plate, and the rigid coupling has the outlet duct of deriving gas between closing plate and the similar filter screen.

Preferably, the cleaning mechanism comprises a rotating shaft rotatably arranged on a sealing plate, a connecting rod is fixedly connected on the sealing plate, a plurality of filter screens are fixedly connected on the connecting rod, a plurality of hairbrushes respectively attached to the similar filter screens are fixedly connected on the rotating shaft, a weight plate is fixedly connected on the sealing plate, a transmission shaft is rotatably arranged on the weight plate, a bevel gear for meshed transmission is fixedly connected on the rotating shaft and the end part of the transmission shaft, a rack is fixedly connected on a sintering furnace main body, a spur gear for meshed transmission with the rack is fixedly connected on the end part of the transmission shaft, and a driving assembly for pushing the weight plate and a plurality of filter screens arranged on the weight plate to move outside the treatment tank is further arranged on the sintering furnace main body.

Preferably, the driving assembly comprises a motor fixedly arranged on the sintering furnace main body, the output end of the motor is fixedly connected with a screw rod, the sintering furnace main body is fixedly connected with a sliding rod, and the weight bearing plate is respectively in threaded connection and sliding connection with the screw rod and the sliding rod.

Preferably, a plurality of filter screens are all connected with the rotating shaft in a sliding way, and the filter screens are attached to the inner wall of the heat conducting sleeve.

Preferably, the upper side and the lower side of the treatment tank are respectively fixedly connected with a water inlet pipe and a water outlet pipe which are communicated with the water storage cavity.

Preferably, the cleaning mechanism further comprises a waste box arranged at one side of the treatment tank, and the waste box is positioned below the heat conducting sleeve.

By means of the technical scheme, the utility model provides rotary powder sintering furnace equipment with pressure, which has the following beneficial effects:

1. this rotary powder sintering furnace equipment with pressure, through setting up recovery mechanism, the gaseous heat that enters into the heat conduction cover through the honeycomb duct that sintering furnace main part processing produced in, the heat conduction cover carries out recycle with the heat in the gas to the water of water storage chamber, and the setting of a plurality of filter screens, can filter the impurity in the gas to and can slow down the speed that the gas flows, make the time of gas and heat conduction cover contact long, the heat in the gas that can be more passes through the heat conduction cover conduction and gives in the water, further improves the quality of energy recovery.

2. This rotary powder sintering furnace equipment with pressure through setting up clearance mechanism, and the brush can clear up the impurity on the filter screen, and then when the filter screen all removes the treatment jar outside, can take out the impurity to can realize automatic clearance to the filter screen, avoid the filter screen to block up and can't carry out conveying gas, can guarantee the normal use of equipment, and need not the manual work and clear up, labour saving and time saving has reduced staff's intensity of labour.

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 application:

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the recovery mechanism of the present utility model;

FIG. 3 is a schematic view of the external connection structure of the treatment tank of the present utility model;

FIG. 4 is a schematic view of a cleaning mechanism according to the present utility model.

Reference numerals:

101. a sintering furnace main body; 102. a treatment tank; 103. a flow guiding pipe;

200. a recovery mechanism; 201. a water storage chamber; 202. a heat conducting sleeve; 203. a filter screen; 204. a sealing plate; 205. an air outlet pipe;

300. a cleaning mechanism; 301. a rotating shaft; 302. a brush; 303. a transmission shaft; 304. bevel gears; 305. spur gears; 306. a rack; 307. a weight plate; 308. waste material box.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

A rotary powder sintering furnace apparatus with pressure according to some embodiments of the present utility model is described below with reference to the accompanying drawings.

Embodiment one:

referring to fig. 1, 2 and 3, the rotary powder sintering furnace device with pressure provided by the utility model comprises a sintering furnace main body 101, a treatment tank 102 is arranged at one side of the sintering furnace main body 101, a flow guide pipe 103 for conveying gas is arranged between the sintering furnace main body 101 and the treatment tank 102, a recovery mechanism 200 for recovering gas heat and purifying gas is arranged in the treatment tank 102, a cleaning mechanism 300 for cleaning impurities in the treatment tank 102 is also arranged on the sintering furnace main body 101, the recovery mechanism 200 comprises a heat conducting sleeve 202 fixedly connected in the treatment tank 102 and connected with the flow guide pipe 103 and used for conducting heat, a water storage cavity 201 for storing liquid is arranged in the treatment tank 102, a plurality of filter screens 203 for filtering gas are arranged in the heat conducting sleeve 202, the one end rigid coupling that heat conduction cover 202 kept away from honeycomb duct 103 has closing plate 204, the rigid coupling has the outlet duct 205 of export gas between closing plate 204 and the close filter screen 203, the gas that sintering furnace main part 101 processing produced enters into heat conduction cover 202 through honeycomb duct 103 in, heat conduction cover 202 passes the heat in the gas to the water of giving water storage chamber 201, can carry out recycle to the energy in the gas, and the setting of a plurality of filter screens 203, can filter the impurity in the gas, and can slow down the speed of gas flow, make the time of gas and heat conduction cover 202 contact long, the heat in the gas that can be more is through heat conduction cover 202 conduction water, further improve the quality of energy recuperation, and can clear up filter screen 203 propelling movement, guarantee the normal operating of equipment through cleaning mechanism 300.

Specifically, the upper and lower sides of the treatment tank 102 are fixedly connected with a water inlet pipe and a water outlet pipe which are communicated with the water storage cavity 201 respectively, water can be injected into the water storage cavity 201 through the water inlet pipe, and the water outlet pipe can discharge the heated water for people to use.

According to the embodiment, the recovery mechanism 200 is utilized to filter impurities in the gas, and also can utilize energy in the gas, so that the energy-saving and environment-friendly effects are facilitated, the damage to the external environment and people can be reduced, the plurality of filter screens 203 are arranged, the effect of purifying the gas can be improved, the water is heated first, and when the temperature of the water in the water storage cavity 201 is equal to that of the gas, water can be changed, and heat recovery is performed again.

Embodiment two:

referring to fig. 1-4, on the basis of the first embodiment, the cleaning mechanism 300 includes a rotating shaft 301 rotatably mounted on a sealing plate 204, a connecting rod is fixedly connected on the sealing plate 204, a plurality of filter screens 203 are fixedly connected on the connecting rod, a plurality of brushes 302 respectively attached to the adjacent filter screens 203 are fixedly connected on the rotating shaft 301, a loading plate 307 is fixedly connected on the sealing plate 204, a transmission shaft 303 is rotatably mounted on the loading plate 307, bevel gears 304 engaged with the transmission shaft 301 are fixedly connected on the ends of the rotating shaft 301 and the transmission shaft 303, racks 306 are fixedly connected on the sintering furnace main body 101, a straight gear 305 engaged with the racks 306 is fixedly connected on the ends of the transmission shaft 303, a driving assembly for pushing the loading plate 307 and a plurality of filter screens 203 arranged on the loading plate 307 are further arranged on the sintering furnace main body 101 to move to the outside of the processing tank 102, the driving assembly drives the loading plate 307 and the filter screens 203 on the sealing plate 204 to move to the outside of the processing tank 102, the straight gear 305 is meshed with the racks 306 to drive the transmission shaft 303, the bevel gears 304 drive the brush 302 to rotate, the bevel gears 302 can clean impurities on the filter screens 203, and then the filter screens 203 can be automatically moved to the outside the processing tank 102, the filter screens 203 can be automatically blocked by the driving assembly, the manual cleaning device can be avoided, and the labor can be saved, and the device can be cleaned.

Specifically, the driving assembly comprises a motor fixedly arranged on the sintering furnace main body 101, a screw rod is fixedly connected to the output end of the motor, a slide rod is fixedly connected to the sintering furnace main body 101, the weight plate 307 is respectively connected to the screw rod and the slide rod in a threaded mode and in a sliding mode, the motor starts to drive the screw rod to rotate, the screw rod rotates to drive the weight plate 307 to move, and then the parts on the weight plate 307 can be driven to move, so that impurity treatment is completed.

Further, the plurality of filter screens 203 are all in sliding connection with the rotating shaft 301, and the filter screens 203 are attached to the inner wall of the heat conducting sleeve 202, so that the heat conducting sleeve 202 can be sealed, and gas is prevented from flowing out.

Still further, the cleaning mechanism 300 further includes a waste box 308 disposed at one side of the treatment tank 102, the waste box 308 is disposed below the heat conducting sleeve 202, and the waste box 308 is disposed to collect the cleaned impurities intensively, so that the workers can process the impurities subsequently.

According to the embodiment, after the cleaning is completed, the motor drives the screw rod to rotate reversely, so that the weight plate 307 resets the sealing plate 204 and the filter screen 203 and moves to the inside of the heat conducting sleeve 202, thereby completing the cleaning of the filter screen 203, and then continuing the gas treatment, and repeating the above steps, thereby continuously recovering and purifying the energy of the gas.

As can be seen from the above examples: the gas generated by the processing of the sintering furnace main body 101 enters the heat conducting sleeve 202 through the flow guiding pipe 103, the heat in the gas is transferred to water in the water storage cavity 201 through the heat conducting sleeve 202, a plurality of filter screens 203 can filter impurities in the gas, then the gas is discharged through the air outlet pipe 205, when the impurities on the filter screens 203 are excessive, when the impurities need to be cleaned, a motor is started to drive a screw rod to rotate, the screw rod is rotated to drive the loading plate 307 to move, then the sealing plate 204 on the loading plate 307 and the filter screens 203 can be driven to move to the outside of the treatment tank 102, the spur gear 305 is meshed with the rack 306 to drive the transmission shaft 303 to rotate, the bevel gear 304 on the transmission shaft 303 drives the brush 302 to rotate through the bevel gear 304, the brush 302 can clean the impurities on the filter screens 203, then when the filter screens 203 are all moved to the outside of the treatment tank 102, the impurities can be carried out, the impurities fall into the waste box 308, and then the motor drives the screw rod to rotate reversely, so that the loading plate 307 can reset the sealing plate 204 and the filter screens 203.

It should be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A rotary pressurized powder sintering furnace device comprising a sintering furnace body (101), characterized in that: a treatment tank (102) is arranged on one side of the sintering furnace main body (101), a flow guide pipe (103) for conveying gas is arranged between the sintering furnace main body (101) and the treatment tank (102), a recovery mechanism (200) for recovering gas heat and purifying gas is arranged in the treatment tank (102), and a cleaning mechanism (300) for cleaning impurities in the treatment tank (102) is also arranged on the sintering furnace main body (101);

the recovery mechanism (200) comprises a heat conduction sleeve (202) which is fixedly connected in the treatment tank (102) and is connected with the flow guide pipe (103) and is commonly used for conducting heat, a water storage cavity (201) for storing liquid is arranged in the treatment tank (102), a plurality of filter screens (203) for filtering gas are arranged in the heat conduction sleeve (202), one end, far away from the flow guide pipe (103), of the heat conduction sleeve (202) is fixedly connected with a sealing plate (204), and an air outlet pipe (205) for leading out gas is fixedly connected between the sealing plate (204) and the similar filter screens (203).

2. The rotary pressured powder sintering furnace apparatus of claim 1, wherein: the cleaning mechanism (300) comprises a rotating shaft (301) rotatably arranged on a sealing plate (204), a connecting rod is fixedly connected on the sealing plate (204), a plurality of filter screens (203) are fixedly connected on the connecting rod, a plurality of brushes (302) which are respectively attached to the similar filter screens (203) are fixedly connected on the rotating shaft (301), a loading plate (307) is fixedly connected on the sealing plate (204), a transmission shaft (303) is rotatably arranged on the loading plate (307), bevel gears (304) which are meshed and driven are fixedly connected on the rotating shaft (301) and the end parts of the transmission shaft (303), racks (306) are fixedly connected on the sintering furnace main body (101), spur gears (305) which are meshed and driven with the racks (306) are fixedly connected on the end parts of the transmission shaft (303), and a driving assembly which is used for pushing the loading plate (307) and the filter screens (203) arranged on the loading plate (307) to move outside the treatment tank (102) is further arranged on the sintering furnace main body (101).

3. The rotary pressured powder sintering furnace apparatus of claim 2, wherein: the driving assembly comprises a motor fixedly arranged on the sintering furnace main body (101), a screw rod is fixedly connected to the output end of the motor, a sliding rod is fixedly connected to the sintering furnace main body (101), and the loading plate (307) is respectively connected to the screw rod and the sliding rod in a threaded and sliding mode.

4. The rotary pressured powder sintering furnace apparatus of claim 2, wherein: the plurality of filter screens (203) are all in sliding connection with the rotating shaft (301), and the filter screens (203) are attached to the inner wall of the heat conducting sleeve (202).

5. The rotary pressured powder sintering furnace apparatus of claim 1, wherein: the upper side and the lower side of the treatment tank (102) are fixedly connected with a water inlet pipe and a water outlet pipe which are communicated with the water storage cavity (201) respectively.

6. The rotary pressured powder sintering furnace apparatus of claim 2, wherein: the cleaning mechanism (300) further comprises a waste box (308) arranged on one side of the treatment tank (102), and the waste box (308) is positioned below the heat conducting sleeve (202).