CN214502123U - Energy-saving type observation door - Google Patents

Abstract

The utility model relates to an energy-saving observation door, including observation brick, door frame, door closure, the observation brick sets up at the heating furnace oven inboard, and the door frame sets up in the heating furnace oven outside, and door closure and door frame block are equipped with door closure heat insulating assemblies to the door closure inboard, the door frame inboard is equipped with door frame heat insulating module, door frame heat insulating module pass through the bolt and heating furnace oven are fixed; the door cover is hinged with the crank assembly up and down, the crank assembly is hinged with the connecting rod assembly, the connecting rod assembly is hinged with the second sleeve, and the second sleeve is fixed on the door frame. The utility model is only suitable for negative pressure heating furnace, the door cover and the door frame adopt the hidden switch self-locking design, and the sealing effect is ensured; the heat loss is reduced by arranging a plurality of heat insulation defense lines; the door closure is drawn out the door frame perpendicularly earlier, then opens completely through the upset of three activity pin joint, and this mode need not be to door closure inside lining local section cut thin, can not produce local high temperature phenomenon.

Description

Energy-saving type observation door

Technical Field

The utility model relates to an industrial heating furnace equipment technical field, concretely relates to energy-saving observation door.

Background

The operation condition in the heating furnace needs to be observed and detected from time to time in the process of operation, detection and maintenance of the heating furnace, and the observation through the observation door is a simpler and more intuitive means except a remote transmission instrument, so the observation door becomes an indispensable component on the heating furnace.

Traditional observation door is when using, and operating personnel rotates earlier and opens observation door closure, then through observation hole direct observation stove interior condition, and open observation hole has directly communicated furnace and external environment, because heating furnace pressure is dynamic change, so scald when operating personnel is observed to the stove in by stove high temperature flue gas and arouse bodily injury easily. In addition, the open type observation hole of the traditional observation door also becomes a conduction channel of heat in the furnace, because the temperature of the installation position of the observation door is usually very high, although the observation door is covered by refractory castable serving as a heat insulation layer, the observation door is limited in structure, the heat insulation layer needs to be cut to be thin so as to avoid the opening rotation angle of the observation door, the observation door can be opened smoothly, the heat insulation layer is thicker, the door cover needs to be cut to be thinner and thinner, so that the local serious overtemperature of the outer surface of the observation door is caused, the heat loss of the heating furnace is increased, the heat efficiency of the heating furnace is reduced, and the energy consumption is increased.

In addition, if the door cover and the door frame are not completely sealed, high-temperature smoke can escape from gaps between the door cover and the door frame, and operators are injured.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects, and provides an energy-saving observation door which is only suitable for a negative pressure heating furnace and has simple structure, the door cover and the door frame adopt a hidden switch self-locking design, and the observation door cover and the door frame are tightly and firmly closed through a built-in column cap plunger, so that the sealing effect is ensured; the heat loss is reduced by arranging a plurality of heat insulation defense lines of the fire observation bricks, the door frame heat insulation module and the door cover heat insulation module; adopt the door closure to pull out the door frame perpendicularly earlier, then through the mode that three activity pin joint upset was opened completely, this mode need not cut thin to door closure inside lining part, can not produce local high temperature phenomenon.

The purpose of the utility model is realized like this:

an energy-saving observation door comprises an observation brick, a door frame and a door cover, wherein the observation brick is arranged on the inner side of the furnace wall of a heating furnace, the door frame is arranged on the outer side of the furnace wall of the heating furnace, the door cover is clamped with the door frame, a door cover heat insulation assembly is arranged on the inner side of the door cover, a door frame heat insulation module is arranged on the inner side of the door frame, and the door frame heat insulation module are fixed with the furnace wall of the heating furnace through bolts; the door cover is hinged with the crank assembly up and down, the crank assembly is hinged with the connecting rod assembly, the connecting rod assembly is hinged with the second sleeve, and the second sleeve is fixed on the door frame.

Preferably, the door cover is hinged with the crank assembly through a first sleeve, a column head plunger is arranged in the first sleeve, a column head of the column head plunger extends into the door cover, a limiting groove is formed in the door frame corresponding to the column head of the column head plunger, and the column head plunger is limited in the first sleeve through a plug screw.

Preferably, the crank assembly is connected with the connecting rod assembly through a first rotating shaft, the connecting rod assembly is connected with the second sleeves through a second rotating shaft, and the second rotating shaft is limited between the two second sleeves.

Preferably, the door cover heat insulation assembly comprises a door cover heat insulation module, and the screw penetrates out of the inner side of the door cover heat insulation module and then sequentially sleeves the fixing plate, the small heat insulation pad, the large heat insulation pad and the door cover, and the screw is fixed through the screw cap.

Preferably, the large insulating mat contacts the outer end face of the door frame in the closed state of the fire door.

Preferably, the second rotating shaft is connected with a limiting round steel, and the limiting round steel is perpendicular to the door frame when the door cover is in the fully closed position.

Preferably, the crank assembly comprises a crank, a joint and a connecting pipe, the joint is sleeved outside the first sleeve, the connecting pipe is sleeved on the first rotating shaft, the crank and the connecting pipe are welded when the door cover is in a closed state, and the connecting rod assembly and the door frame form an angle of 90 degrees.

Preferably, the fire-viewing brick, the door frame heat insulation module and the door cover heat insulation module are all formed by VF-14 type ceramic fiber vacuum forming modules.

The utility model has the advantages that:

1. the door cover and the door frame adopt a hidden switch self-locking design, and the fire observation door cover and the door frame are tightly and firmly closed through a built-in column head plunger, so that the sealing effect is ensured;

2. the fire brick, the door frame heat insulation module and the door cover heat insulation module are all formed by VF-14 type ceramic fiber vacuum forming blocks, so that the weight is lighter, the temperature resistance is higher, and the heat insulation effect is better, thereby reducing the heat loss;

3. the opening mode of the fire door is as follows: the door closure is drawn out the door frame perpendicularly earlier, then opens completely through the upset of three activity pin joint, and this mode need not be to door closure inside lining local section cut thin, can not produce local high temperature phenomenon.

Drawings

Fig. 1 is a front view of the energy-saving observation door of the present invention.

Fig. 2 is a left side view of fig. 1.

Fig. 3 is a partial enlarged view I of fig. 2.

Fig. 4 is a sectional view a-a of fig. 1.

Fig. 5 is an opening trace diagram of the door cover.

Fig. 6 is a view from the direction B of fig. 1 (the door is in a fully closed state).

FIG. 7 is a schematic view of a door insulating assembly.

Wherein: 1, viewing a fire brick; a door frame 2; a limiting groove 2.1; a door cover 3; a first sleeve 3.1; a furnace wall 4 of the heating furnace; a door panel insulation assembly 5; a door cover heat insulation module 5.1; 5.2 parts of a screw rod; a fixed plate 5.3; a small thermal insulation pad 5.4; 5.5 of a large heat insulation pad; 5.6 of a screw cap; a door frame heat insulation module 6; a crank assembly 7; a crank 7.1; a joint 7.2; 7.3, connecting pipes; a connecting rod assembly 8; a connecting plate 8.1; a third sleeve 8.2; a fourth sleeve 8.3; a second sleeve 9; a column head plunger 10; a plug screw 11; a first rotating shaft 12; a second rotating shaft 13; limiting round steel 14; a cushion pad 15; a door frame insulating spacer 16.

Detailed Description

Referring to the figures 1-7, the utility model relates to an energy-saving observation door, including seeing fire brick 1, door frame 2, door closure 3, seeing that fire brick 1 sets up at 4 inboards of heating furnace oven, door frame 2 sets up in 4 outsides of heating furnace oven, door closure 3 and 2 blocks of door frame, and 3 inboards of door closure are equipped with door closure thermal-insulated subassembly 5, 2 inboards of door frame are equipped with door frame thermal-insulated module 6, door frame 2, door frame thermal-insulated module 6 pass through the bolt and are fixed with heating furnace oven 4.

The door is characterized in that a first sleeve 3.1 is arranged above and below the door cover 3, the first sleeve 3.1 is hinged to a crank assembly 7, the crank assembly 7 is hinged to a connecting rod assembly 8, the connecting rod assembly 8 is hinged to a second sleeve 9, and the second sleeve 9 is fixed on the door frame 2. The crank assembly 7 is connected with the connecting rod assembly 8 through a first rotating shaft 12, the connecting rod assembly 8 is connected with the second sleeves 9 through a second rotating shaft 13, and the second rotating shaft 13 is limited between the two second sleeves 9. Realize the flexibility of door closure through three movable pin joints and open, ensure that the door closure can open completely, do not block the viewing aperture.

A column head plunger 10 is arranged in the first sleeve 3.1, a column head of the column head plunger 10 extends into the door cover 3, a limiting groove 2.1 is arranged on the door frame 2 corresponding to the column head of the column head plunger 10, and the column head plunger 10 is limited in the first sleeve 3.1 by a screw plug 11.

The door cover heat insulation assembly 5 comprises a door cover heat insulation module 5.1, a screw rod 5.2 penetrates out of the inner side of the door cover heat insulation module 5.1 to the outer side and then is sequentially sleeved with a fixing plate 5.3, a small heat insulation pad 5.4, a large heat insulation pad 5.5 and a door cover 3, the fixing is realized through a nut 5.6, the large heat insulation pad 5.5 is in contact with the outer end face of the door frame 2 in the closing state of the observation door, and a zero gap between the door cover and the door frame is ensured.

Second pivot 13 connects spacing round steel 14, spacing round steel 14 welds when the door closure is adjusted to the position of closing entirely, and spacing round steel 14 perpendicular to door frame 2 when guaranteeing the door closure position of closing entirely. This is done to enable the door cover to be positioned vertically just above the door frame when closed, thereby enabling accurate vertical clamping of the door frame.

A buffer cushion 15 is arranged between the door frame heat insulation module 6 and the door cover heat insulation module 5.1, the buffer cushion 15 is adhered to the door cover heat insulation module 5.1 through a high-temperature adhesive during installation, and the buffer cushion 15 is made of a ceramic fiber felt material.

When the door frame heat insulation module 6 is installed in the door frame 2, a high-temperature adhesive is coated on the contact surface of the inner side of the door frame 2 and then construction is performed.

The crank component 7 comprises a crank 7.1, a connector 7.2 and a connecting pipe 7.3, the connector 7.2 is sleeved outside the first sleeve 3.1, and the connecting pipe 7.3 is sleeved on the first rotating shaft 12.

The welding of the crank 7.1 to the connecting pipe 7.3 needs to be carried out when the door cover 3 is in the closed state, i.e. the connecting rod assembly 7 is at 90 ° to the door frame 2.

The connecting rod assembly 8 comprises a connecting plate 8.1, a third sleeve 8.2 and a fourth sleeve 8.3, the third sleeve 8.2 and the fourth sleeve 8.3 are arranged on two sides of the connecting plate 8.1, the third sleeve 8.3 is sleeved with the first rotating shaft 12, the fourth sleeve 8.3 is sleeved with the second rotating shaft 13, and the connecting plate 8.1 is welded with the second rotating shaft 13.

The fire-viewing brick 1, the door frame heat insulation module 6 and the door cover heat insulation module 5.1 are all formed by VF-14 type ceramic fiber vacuum forming modules.

And a door frame heat insulation gasket 16 is also arranged between the furnace wall 4 and the door frame of the heating furnace, one end of the door frame heat insulation module 6 extends into the heating furnace from the furnace wall, and the end surface is contacted with the end surface of the flame observation brick to realize sealing.

When the door frame heat insulation module 6 is provided with the door frame heat insulation gasket 16 to the outer side of the door frame heat insulation module, a high-temperature adhesive is coated on the contact surface of the door frame heat insulation module and the door frame.

The working principle is as follows: the door cover is pulled outwards along the direction vertical to the furnace wall, the column head of the column head plunger is separated from the limiting groove to remove self-locking, at the moment, the crank assembly rotates around the first rotating shaft, and after the door cover is vertically pulled out of the door frame, the crank assembly and the connecting rod assembly integrally rotate around the second rotating shaft until the fire observation door is completely opened.

In addition to the above embodiments, the present invention also includes other embodiments, and all technical solutions formed by equivalent transformation or equivalent replacement should fall within the protection scope of the claims of the present invention.

Claims (8)

1. An energy-saving observation door, its characterized in that: the fireproof door comprises fireproof bricks (1), a door frame (2) and a door cover (3), wherein the fireproof bricks (1) are arranged on the inner side of a heating furnace wall (4), the door frame (2) is arranged on the outer side of the heating furnace wall (4), the door cover (3) is clamped with the door frame (2), a door cover heat insulation component (5) is arranged on the inner side of the door cover (3), a door frame heat insulation module (6) is arranged on the inner side of the door frame (2), and the door frame (2) and the door frame heat insulation module (6) are fixed with the heating furnace wall (4) through bolts; the door is characterized in that the door cover (3) is hinged with a crank assembly (7) up and down, the crank assembly (7) is hinged with a connecting rod assembly (8), the connecting rod assembly (8) is hinged with a second sleeve (9), and the second sleeve (9) is fixed on the door frame (2).

2. An energy efficient fire door as defined in claim 1, wherein: the door closure (3) is hinged with the crank assembly (7) through the first sleeve (3.1), a column head plunger (10) is arranged in the first sleeve (3.1), a column head of the column head plunger (10) extends into the door closure (3), a limiting groove (2.1) is formed in the position, corresponding to the column head plunger (10), of the door frame (2), and the column head plunger (10) is limited in the first sleeve (3.1) through the screw plug (11).

3. An energy efficient fire door as defined in claim 1, wherein: the crank assembly (7) is connected with the connecting rod assembly (8) through a first rotating shaft (12), the connecting rod assembly (8) is connected with the second sleeve (9) through a second rotating shaft (13), and the second rotating shaft (13) is limited between the two second sleeves (9).

4. An energy efficient fire door as defined in claim 1, wherein: door closure heat insulating assembly (5) including door closure heat insulating module (5.1), fixed plate (5.3), little heat insulating mattress (5.4), big heat insulating mattress (5.5) and door closure (3) are cup jointed in proper order after screw rod (5.2) are worn out to the outside from door closure heat insulating module (5.1) inboard, are fixed through nut (5.6).

5. An energy efficient fire door as defined in claim 4, wherein: when the observation door is closed, the large heat insulation pad (5.5) is contacted with the outer end surface of the door frame (2).

6. An energy efficient fire door as defined in claim 3, wherein: the second rotating shaft (13) is connected with limiting round steel (14), and the limiting round steel (14) is perpendicular to the door frame (2) when the door cover is in the fully closed position.

7. An energy efficient fire door as defined in claim 1, wherein: crank subassembly (7) include crank (7.1), connect (7.2) and take over (7.3), connect (7.2) cover to establish outside first sleeve (3.1), take over (7.3) cover to establish on first pivot (12), crank (7.1) and the welding of taking over (7.3) need be in the closed condition in door closure (3), and link assembly (8) are gone on when door frame (2) become 90.

8. An energy efficient fire door as defined in claim 1, wherein: the fire observation brick (1), the door frame heat insulation module (6) and the door cover heat insulation module (5.1) are all formed by VF-14 type ceramic fiber vacuum forming blocks.

Images