CN215724546U - Dual temperature control type cooling equipment for cement clinker - Google Patents

Abstract

The utility model discloses cement clinker dual temperature control type cooling equipment which comprises an outer barrel, wherein a main barrel is fixedly arranged in the middle of the inner part of the outer barrel, a temperature control equipment body is arranged on the front side surface of the outer barrel, an air cooler is integrally arranged at the bottom of the outer barrel, side boxes are arranged on the outer walls of the left side and the right side of the outer barrel in an embedded mode, a return pipe is arranged on the rear side of the inner part of each side box, a flow transmission pipe is arranged on the front side of the inner part of each side box, and a placing barrel is arranged in the main barrel. Through the setting of cavity mechanism, let the inside of outer bucket be the cavity form, block thermal direct conduction, avoid the outer wall high temperature of outer bucket, through the setting of defeated flow connecting pipe and backward flow connecting pipe, let defeated flow connecting pipe and backward flow connecting pipe respectively with outside side incasement portion defeated flow pipe and back flow interconnect, let the water in the side case can circulate and flow in the inside of defeated flow connecting pipe and backward flow connecting pipe like this, take away the inside heat of cavity mechanism with the help of cold water.

Description

Dual temperature control type cooling equipment for cement clinker

Technical Field

The utility model relates to the field of cooling equipment, in particular to cement clinker dual temperature control type cooling equipment.

Background

The cement clinker uses limestone, clay and iron raw materials as main raw materials, the raw materials are prepared into raw materials according to a proper proportion, the raw materials are burnt until the raw materials are partially or completely melted, and the raw materials are cooled to obtain a semi-finished product.

The existing cement clinker cooling equipment has poor cooling effect in the use process, can not realize dual temperature control cooling, causes insufficient cooling efficiency and prolongs the cooling working time.

Therefore, it is necessary to develop a dual temperature-controlled cooling apparatus for cement clinker to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide cement clinker dual temperature control type cooling equipment to solve the problems that the existing cement clinker cooling equipment is poor in cooling effect, cannot realize dual temperature control cooling, is insufficient in cooling efficiency and prolongs cooling working time in the use process.

In order to achieve the above purpose, the utility model provides the following technical scheme: the utility model provides a dual control by temperature change formula cooling arrangement of cement clinker, includes outer bucket, fixed mounting has main bucket in the middle of the inside of outer bucket, and the front side surface mounting of outer bucket has the control by temperature change equipment body, the air-cooler is installed in the bottom integration of outer bucket, the equal gomphosis of the left and right sides outer wall of outer bucket is provided with the side case, and the inside rear side of side case is provided with the back flow, the defeated flow pipe is installed to the inside front side of side case, the inside arrangement of main bucket has the bucket of placing, and the inside axis of placing the bucket installs the tuber pipe, the fixed heat dissipation mechanism that is provided with in the middle of the inside of main bucket, the outside skin weld of placing the bucket has the reinforcement seat.

Preferably, the inner wall of the outer barrel comprises a hollow mechanism, a flow transmission connecting pipe, a backflow connecting pipe and a ceramic heat conducting rod, the flow transmission connecting pipe is connected to the inner wall of the hollow mechanism in an inserting mode, the backflow connecting pipe is arranged below the flow transmission connecting pipe, and the ceramic heat conducting rod is fixedly arranged on the inner wall of the hollow mechanism in a penetrating mode.

Preferably, the length of the flow transmission connecting pipe is consistent with that of the backflow connecting pipe, and the flow transmission connecting pipe and the backflow connecting pipe are both arranged in a concave shape along the internal structure shape of the hollow mechanism.

Preferably, the inside of placing the bucket is including draw-in groove, kelly, track, pivot, plectrum and location spout, and the inner wall integration of draw-in groove is connected with the kelly, the track is installed in the outside of kelly, and the surface of track has seted up the location spout, it is the block connection between location spout and the kelly, the inner wall of track is provided with the plectrum, and the pivot is installed to the bottom of track.

Preferably, the placing barrel is in sliding connection with the crawler through the clamping rod, and the poking sheets are uniformly distributed along the inner surface of the crawler.

Preferably, the surface of the air pipe comprises a spiral pipe and air holes, and the air holes are formed in the surface of the spiral pipe.

Preferably, the symmetrical axis of the spiral pipe and the central axis of the air pipe are coincident, and one side of the inner wall of the spiral pipe is communicated with the air pipe.

Preferably, the surface of the heat dissipation mechanism comprises a communication pipe, a through hole and a heat conduction pipe, the through hole is formed in the inner wall of the communication pipe, and the heat conduction pipes are connected to the left side and the right side of the communication pipe.

Preferably, the through-holes are uniformly distributed along the vertical direction of the surface of the communicating pipe, and the heat conducting pipes are distributed on the left side and the right side of the communicating pipe in an L shape.

In the technical scheme, the utility model provides the following technical effects and advantages:

1. the inner part of the outer barrel is hollow through the arrangement of the hollow mechanism, the direct conduction of heat is blocked, the overhigh temperature of the outer wall of the outer barrel is avoided, the flow transmission connecting pipe and the backflow connecting pipe are respectively connected with the flow transmission pipe and the backflow pipe in the outer side box through the arrangement of the flow transmission connecting pipe and the backflow connecting pipe, so that water in the side box can circularly flow in the flow transmission connecting pipe and the backflow connecting pipe, and the heat in the hollow mechanism is taken away by means of cold water;

2. the arrangement of the placing barrels can place cement clinker, meanwhile, four groups of placing barrels are arranged inside the main barrel, so that the cement clinker can be placed and cooled in batches, the cooling speed can be accelerated, the clamping rods are connected with the positioning sliding grooves on the surface of the crawler belt, the clamping rods and the positioning sliding grooves are in sliding connection, and the arrangement of the arc-shaped shifting pieces can turn the bottom of the cement clinker to the upper side after the crawler belt rotates, so that the cement clinker is cooled more quickly and thoroughly;

3. the air pipe is arranged, so that cold air generated by the air cooler can be guided into the main barrel, cold air circulation can be formed in the main barrel, heat inside the main barrel can be accelerated to be consumed, the spiral pipe is communicated with the air pipe, so that the air guided from the air pipe can enter the spiral pipe and is emitted outwards along the spiral shape of the spiral pipe, and the whole main barrel can be filled with the air from top to bottom;

4. through the setting of heat dissipation mechanism, communicate each other between heat dissipation mechanism and the communicating pipe, so, be favorable to flowing heat in the mechanism that dispels the heat and the heat in the communicating pipe each other, slow down pressure, the heat pipe is located the both sides of communicating pipe, the metal material that the copper aluminium that the heat pipe adopted combines is made, combines copper aluminium heat conductivility between them, and the cost is not just too high for the cost of full copper, the price/performance ratio is good, what heat dissipation mechanism adopted is the ceramic material, can carry out heat conduction.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

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

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

FIG. 3 is a schematic view of an inner structure of an outer tub according to the present invention;

FIG. 4 is a schematic view of the structure of the placement barrel of the present invention;

FIG. 5 is a schematic view of the internal structure of the track of the present invention;

FIG. 6 is a schematic structural diagram of a heat dissipation mechanism according to the present invention;

fig. 7 is an enlarged schematic view of the structure of fig. 4 at a.

Description of reference numerals:

the device comprises an outer barrel 1, a hollow mechanism 101, a flow transmission connecting pipe 102, a backflow connecting pipe 103, a ceramic heat conducting rod 104, a main barrel 2, a temperature control equipment body 3, an air cooler 4, a side box 5, a backflow pipe 6, a flow transmission pipe 7, a placement barrel 8, a clamping groove 801, a clamping rod 802, a crawler belt 803, a rotating shaft 804, a stirring sheet 805, a positioning sliding groove 806, an air pipe 9, a spiral pipe 901, an air hole 902, a heat dissipation mechanism 10, a communicating pipe 1001, a through hole 1002, a heat conducting pipe 1003 and a reinforcing seat 11.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

The utility model provides cement clinker double temperature control type cooling equipment as shown in figures 1-7, which comprises an outer barrel 1, wherein a main barrel 2 is fixedly arranged in the middle of the inner part of the outer barrel 1, a temperature control equipment body 3 is arranged on the front side surface of the outer barrel 1, an air cooler 4 is integrally arranged at the bottom of the outer barrel 1, side boxes 5 are respectively embedded and arranged on the outer walls of the left side and the right side of the outer barrel 1, a return pipe 6 is arranged on the rear side of the inner part of each side box 5, a flow transmission pipe 7 is arranged on the front side of the inner part of each side box 5, a placing barrel 8 is arranged in the main barrel 2, an air pipe 9 is arranged on the central axis of the inner part of each placing barrel 8, a heat dissipation mechanism 10 is fixedly arranged in the middle of the inner part of the main barrel 2, a reinforcing seat 11 is welded on the outer side surface of each placing barrel 8, and an electric connection relationship is formed between the air cooler 4 and the temperature control equipment body 3, so that a central control system controls the air cooler 4 through the temperature control equipment body 3, and then let air-cooler 4 cool down to main barrel 2 inside, communicate each other between tuber pipe 9 and the air-cooler 4, and the wind that air-cooler 4 produced can irritate into main barrel 2's inside through tuber pipe 9 to at inside continuous circulation cold air current of forming of main barrel 2, be favorable to consuming the heat like this, the help cooling.

Further, in the above technical solution: the inner wall of outer bucket 1 is including cavity mechanism 101, defeated flow connecting pipe 102, backward flow connecting pipe 103 and ceramic heat conduction pole 104, and the inner wall of cavity mechanism 101 alternates and is connected with defeated flow connecting pipe 102, the below of defeated flow connecting pipe 102 is provided with backward flow connecting pipe 103, the inner wall of cavity mechanism 101 runs through and is fixed with ceramic heat conduction pole 104, setting through cavity mechanism 101 lets the inside of outer bucket 1 be the cavity form, block thermal direct conduction, avoid outer wall temperature of outer bucket 1 too high.

Further, in the above technical solution: the length of the fluid transmission connecting pipe 102 is consistent with that of the backflow connecting pipe 103, and the fluid transmission connecting pipe 102 and the backflow connecting pipe 103 are both arranged in a concave shape along the internal structure shape of the hollow mechanism 101, and through the arrangement of the fluid transmission connecting pipe 102 and the backflow connecting pipe 103, the fluid transmission connecting pipe 102 and the backflow connecting pipe 103 are respectively connected with the fluid transmission pipe 7 and the backflow pipe 6 inside the outer side box 5, so that water in the side box 5 can circulate inside the fluid transmission connecting pipe 102 and the backflow connecting pipe 103 to flow, and heat inside the hollow mechanism 101 is taken away by cold water.

Further, in the above technical solution: place bucket 8's inside including draw-in groove 801, kelly 802, track 803, pivot 804, plectrum 805 and location spout 806, and the inner wall integration of draw-in groove 801 is connected with kelly 802, track 803 is installed to the outside of kelly 802, and location spout 806 has been seted up on the surface of track 803, it is connected to be the block between location spout 806 and the kelly 802, the inner wall of track 803 is provided with plectrum 805, and the pivot 804 is installed to the bottom of track 803, through the setting of placing bucket 8, can place cement clinker, and simultaneously, it places bucket 8 to be provided with four groups in main bucket 2's inside, be favorable to placing the cooling with cement clinker in batches, can accelerate refrigerated speed like this.

Further, in the above technical solution: place bucket 8 through card pole 802 and track 803, between constitute sliding connection, and plectrum 805 along the internal surface evenly distributed of track 803, utilize card pole 802 to connect the location spout 806 on track 803 surface, be sliding connection between card pole 802 and the location spout 806 and be the setting of arc plectrum 805, can be after track 803 rotates, turn over the bottom of cement clinker to the top, let cement clinker cool off more fast more thoroughly.

Further, in the above technical solution: the surface of tuber pipe 9 is including spiral pipe 901 and wind hole 902, and wind hole 902 has been seted up on the surface of spiral pipe 901, through the setting of tuber pipe 9, can carry out main bucket 2 with the cold wind guide that air-cooler 4 produced to can form the cold wind circulation at main bucket 2, be favorable to accelerating the heat of consuming 2 inside main buckets.

Further, in the above technical solution: the symmetry axis line of spiral pipe 901 coincides with the axis of tuber pipe 9 each other, and communicates each other between inner wall one side of spiral pipe 901 and tuber pipe 9, because communicate each other between spiral pipe 901 and the tuber pipe 9, the wind that draws up from tuber pipe 9 like this can get into in spiral pipe 901 to the spiral shape along spiral pipe 901 is toward dispelling outward, can let wind from the top down and fill up whole main barrel 2 like this.

Further, in the above technical solution: the surface of heat dissipation mechanism 10 is including communicating pipe 1001, through-hole 1002 and heat pipe 1003, and the through-hole 1002 has been seted up to the inner wall of communicating pipe 1001, and the left and right sides of communicating pipe 1001 all is connected with heat pipe 1003, communicates each other between heat dissipation mechanism 10 and the communicating pipe 1001, so, is favorable to flowing heat in the heat dissipation mechanism 10 and the heat in communicating pipe 1001 each other, slows down pressure.

Further, in the above technical solution: through-hole 1002 is along the vertical direction evenly distributed in surface of communicating pipe 1001, and heat pipe 1003 is "L" type and distributes in the left and right sides of communicating pipe 1001, and heat pipe 1003 is located the both sides of communicating pipe 1001, and the metal material that the copper aluminium that heat pipe 1003 adopted combines makes, combines the heat conductivility between copper aluminium, and the cost is not as high as the cost of full copper, and the price/performance ratio is good, and what mechanism 10 adopted that dispels the heat is the ceramic material, can carry out heat conduction.

This practical theory of operation:

referring to the accompanying drawings 1-7 of the specification, the heat in the main barrel 2 and the heat dissipation mechanism 10 in the heat centralized conduction of the placing barrel 8 is dissipated to two sides by the heat conduction pipe 1003, so that the heat is centralized to reach the inner wall position of the main barrel 2, the heat in the main barrel 2 is conducted into the hollow mechanism 101 by the ceramic heat conduction rod 104, meanwhile, the cooling liquid in the side box 5 flows into the hollow mechanism 101 through the flow connection pipe 102 and consumes a part of the heat, then flows into the side box 5 at the other side, the liquid in the side box 5 at the other side is mixed with the input liquid and helps to cool the input liquid, and the cooling liquid enters the hollow mechanism 101 again by the backflow connection pipe 103 so as to circulate back and forth until the heat in the hollow mechanism 101 is completely consumed;

referring to the accompanying drawings 1-7 of the specification, a rotating shaft 804 is utilized, the rotating shaft 804 is driven to rotate by a motor, so that the rotating shaft 804 drives a track 803 to rotate, the track 803 is connected to the inner wall of a placing barrel 8 through a clamping rod 802, the clamping rod 802 is in a T shape and can be transversely clamped inside a positioning chute 806, meanwhile, after the track 803 rotates, the clamping rod 802 moves along the surface of the positioning chute 806, the track 803 is fixed on the inner wall of the placing barrel 8, the clamping rod 802 is utilized to tighten the track 803, the track 803 cannot collapse and deform, the track 803 rotates, a poking piece 805 can turn cement clinker on the bottom layer to the upper layer, heat of the cement clinker is dissipated out as soon as possible, wind led from an air pipe 9 can enter a spiral pipe 901 and can be dissipated outwards along the spiral shape of the spiral pipe 901 through air holes 902, and heat inside a main barrel 2 is accelerated to be consumed.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the utility model.

Claims (9)

1. The utility model provides a dual control by temperature change formula cooling arrangement of cement clinker, includes outer bucket (1), its characterized in that: the temperature control device comprises an outer barrel (1), a main barrel (2) is fixedly mounted in the middle of the inside of the outer barrel (1), a temperature control device body (3) is mounted on the surface of the front side of the outer barrel (1), an air cooler (4) is integrally mounted at the bottom of the outer barrel (1), side boxes (5) are arranged on the outer walls of the left side and the right side of the outer barrel (1) in an embedded mode, a backflow pipe (6) is arranged on the rear side of the inside of each side box (5), a flow transmission pipe (7) is mounted on the front side of the inside of each side box (5), a placement barrel (8) is arranged inside the main barrel (2), an air pipe (9) is mounted on the inner central axis of the placement barrel (8), a heat dissipation mechanism (10) is fixedly arranged in the middle of the inside of the main barrel (2), and a reinforcing seat (11) is welded on the surface of the outer side of the placement barrel (8).

2. The cement clinker dual temperature control type cooling equipment according to claim 1, wherein: the inner wall of the outer barrel (1) comprises a hollow mechanism (101), a flow transmission connecting pipe (102), a backflow connecting pipe (103) and a ceramic heat conducting rod (104), the inner wall of the hollow mechanism (101) is connected with the flow transmission connecting pipe (102) in an inserting mode, the backflow connecting pipe (103) is arranged below the flow transmission connecting pipe (102), and the ceramic heat conducting rod (104) penetrates through and is fixed on the inner wall of the hollow mechanism (101).

3. The cement clinker dual temperature control type cooling equipment according to claim 2, wherein: the length of the flow transmission connecting pipe (102) is consistent with that of the backflow connecting pipe (103), and the flow transmission connecting pipe (102) and the backflow connecting pipe (103) are both arranged in a concave shape along the internal structure shape of the hollow mechanism (101).

4. The cement clinker dual temperature control type cooling equipment according to claim 1, wherein: the inside of placing bucket (8) is including draw-in groove (801), kelly (802), track (803), pivot (804), plectrum (805) and location spout (806), and the inner wall integration of draw-in groove (801) is connected with kelly (802), track (803) are installed to the outside of kelly (802), and location spout (806) have been seted up on the surface of track (803), be the block between location spout (806) and kelly (802) and be connected, the inner wall of track (803) is provided with plectrum (805), and pivot (804) are installed to the bottom of track (803).

5. The cement clinker dual temperature control type cooling equipment according to claim 4, wherein: the placing barrel (8) is in sliding connection with the crawler belt (803) through the clamping rod (802), and the poking sheets (805) are uniformly distributed along the inner surface of the crawler belt (803).

6. The cement clinker dual temperature control type cooling equipment according to claim 1, wherein: the surface of the air pipe (9) comprises a spiral pipe (901) and air holes (902), and the surface of the spiral pipe (901) is provided with the air holes (902).

7. The cement clinker dual temperature control type cooling equipment according to claim 6, wherein: the symmetrical axis line of the spiral pipe (901) is superposed with the central axis of the air pipe (9), and one side of the inner wall of the spiral pipe (901) is communicated with the air pipe (9).

8. The cement clinker dual temperature control type cooling equipment according to claim 1, wherein: the surface of the heat dissipation mechanism (10) comprises a communication pipe (1001), a through hole (1002) and a heat conduction pipe (1003), the through hole (1002) is formed in the inner wall of the communication pipe (1001), and the heat conduction pipe (1003) is connected to the left side and the right side of the communication pipe (1001).

9. The dual temperature controlled cooling apparatus for cement clinker as claimed in claim 8, wherein: the through holes (1002) are uniformly distributed along the vertical direction of the surface of the communication pipe (1001), and the heat conduction pipes (1003) are distributed on the left side and the right side of the communication pipe (1001) in an L shape.

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