CN218453799U - Energy-saving cement warehouse-out cooling device - Google Patents

Abstract

The utility model discloses an energy-saving cement cooling device that goes out of warehouse, including the cooling cylinder, cooling cylinder one end is provided with the transport bucket, and the transport bucket is close to cooling cylinder one side and is provided with cooling mechanism, and cooling mechanism one end is connected with transport assembly, and cooling cylinder one side is provided with the controller, and cooling cylinder one end is provided with out the hopper, the utility model discloses a mutually supporting of above-mentioned each mechanism can guarantee the cooling effect of energy-saving cement partly, is simultaneously through setting up transport assembly, is convenient for when using, stirs the energy-saving cement of carrying and makes its constantly break up, and then makes its cooling area increase to setting up the second on the surface of the conveying rod and carrying the cover, can further guarantee the cooling effect at cooling cylinder middle part.

Description

Energy-saving cement warehouse-out cooling device

Technical Field

The utility model relates to a cement processing technology field particularly, relates to an energy-saving cement heat sink that leaves warehouse.

Background

Energy-saving cement is a common building material, and usually, when the energy-saving cement is processed and then is delivered out of a warehouse, a certain temperature exists, if the temperature of the cement is too high, a series of safety problems such as accelerated hydration, accelerated collapse, shortened setting time or false setting and the like can occur during use, so that the safety of the building is influenced, and therefore, an energy-saving cement delivery out cooling device is needed

By retrieving the energy-saving cement ex-warehouse cooling device disclosed in the Chinese patent CN 208671760U, the cement is cooled by the cooling liquid in the condensation pipeline and the condensation pipeline is blown by the exhaust fan, so that the flow of the cooling liquid is accelerated, the temperature of the cement is reduced, and the problem that the temperature of the cement is too high when the cement is ex-warehouse after being processed is solved.

However, an energy-saving cement goes out of warehouse heat sink still has some problems, and this patent is cooling its cement and blowing to its condensation duct through the air exhauster through the coolant liquid in the condensation duct for the coolant liquid flows, but this patent is in to cooling process, can only cool off its energy-saving cement one side position, and the energy-saving cement that is in placing chamber opposite side and middle part probably can not be cooled off or cool down, thereby leads to energy-saving cement cooling effect relatively poor.

SUMMERY OF THE UTILITY MODEL

To the problem among the correlation technique, the utility model provides an energy-saving cement heat sink of leaving warehouse to overcome the above-mentioned technical problem that current correlation technique exists.

Therefore, the utility model discloses a specific technical scheme as follows:

the utility model provides an energy-saving cement cooling device that leaves warehouse, includes the cooling cylinder, and cooling cylinder one end is provided with the transport bucket, and the transport bucket is close to cooling cylinder one side and is provided with cooling mechanism, and cooling mechanism one end is connected with conveying assembly, and cooling cylinder one side is provided with the controller, and cooling cylinder one end is provided with out the hopper.

Further, for better assurance energy-saving cement cooling effect, cooling mechanism includes the collecting pipe that transport bucket one end set up, and collecting pipe one side sets up the input tube, and input tube one end is provided with the delivery pump, and the input tube is close to the cooling cylinder and is provided with the collecting box.

Further, for better carrying out the dust to the production, delivery pump one end is provided with the output tube, and output tube one side is provided with equidistant conveyer pipe, and the conveyer pipe cover is established on the cooling cylinder surface, and conveyer pipe one side is close to the cooling cylinder and sets up first transport cover, and conveying assembly is connected with output tube one end.

Further, for better assurance energy-saving cement heat dissipation even, conveying assembly includes the hollow motor that output tube one end set up, and hollow motor one end is run through the cooling cylinder and is provided with the delivery rod, and the delivery rod surface is provided with the delivery board, and the delivery board is close to delivery rod one side and is provided with and pulverizes the subassembly.

Further, for better cooling energy-saving cement, the middle of the conveying rod is provided with a conveying cavity, the conveying cavity is close to the conveying rod and is provided with equidistant output holes, and one end of each output hole is provided with a second conveying cover.

Further, for the energy-saving cement that prevents to go out of warehouse has the caking problem, pulverizes the subassembly and includes the first roller that pulverizes that the conveying rod set up, and first roller one end that pulverizes sets up in cooling cylinder one side, and first roller surface that pulverizes is provided with the first piece of pulverizing of equidistance.

Further, for better assurance pulverizes the effect, first pulverize the piece and be provided with equidistant second all around and grind the piece, the second pulverizes piece one side and is provided with the second and smashes the roller, and second is smashed roller one end and is set up in cooling cylinder one side.

Further, for better dust collection and filtration, equidistant collecting holes are formed in one end of the collecting pipe, the collecting box is close to the cooling cylinder and is provided with a conveying opening, and a filter screen is arranged in the collecting box.

The utility model has the advantages that:

(1) Through setting up cooling mechanism on cooling cylinder surface, be convenient for when using, can guarantee the cooling effect of energy-saving cement partly, simultaneously through setting up conveying assembly, be convenient for when using, stir the energy-saving cement of carrying and make it constantly break up, and then make its cooling area increase to through setting up the second on the carriage bar surface and carrying the cover, can further guarantee the cooling effect at cooling cylinder middle part.

(2) The crushing component is arranged on one side of the conveying rod, so that when in use, the energy-saving cement which is discharged from a warehouse and poured into the conveying hopper can be crushed, thereby can avoid the problem that the partial caking problem and the cooling effect that leads to is not good to appear, simultaneously through setting up the collecting pipe, be convenient for when using, absorb the dust that pulverizes or pours the production into to can clean the effect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required 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 of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of an energy-saving cement ex-warehouse cooling device according to an embodiment of the present invention;

fig. 2 is a schematic side view of an energy-saving cement ex-warehouse cooling device according to an embodiment of the present invention;

fig. 3 is a schematic sectional view of an energy-saving cement ex-warehouse cooling device according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a cooling mechanism of an energy-saving cement ex-warehouse cooling device according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a conveying assembly of an energy-saving cement ex-warehouse cooling device according to an embodiment of the present invention;

fig. 6 is a structural schematic diagram of an energy-saving cement ex-warehouse cooling device crushing assembly according to the embodiment of the invention.

In the figure:

1. a cooling cylinder; 2. a conveying hopper; 3. a cooling mechanism; 301. a collection pipe; 302. an input tube; 303. a delivery pump; 304. an output pipe; 305. a delivery pipe; 306. a first delivery hood; 4. a delivery assembly; 401. a hollow motor; 402. a conveying rod; 403. a conveying plate; 5. a controller; 6. a discharge hopper; 7. a collection box; 8. a grinding assembly; 801. a first crushing roller; 802. first grinding the fragments; 803. second grinding the fragments; 804. a second crushing roller; 9. a delivery lumen; 10. a second delivery cover; 11. a collection well; 12. and (4) a filter screen.

Detailed Description

To further illustrate the various embodiments, the present invention provides the accompanying drawings, which are part of the disclosure and which are primarily intended to illustrate embodiments and, together with the description, serve to explain the principles of operation of the embodiments, and, by reference to these drawings, those of ordinary skill in the art will understand the principles of the invention and its advantages, with reference to the drawings and figures, in which elements are not drawn to scale and like elements are generally designated by like reference numerals.

An energy-saving cement warehouse-out cooling device, please refer to fig. 1, which comprises a cooling cylinder 1 for carrying and cooling energy-saving cement; one end of the cooling cylinder 1 is provided with a conveying hopper 2 for conveying the energy-saving cement discharged from the warehouse; a cooling mechanism 3 is arranged on one side of the conveying hopper 2 close to the cooling cylinder 1 and used for cooling the energy-saving cement discharged from the warehouse; one end of the cooling mechanism 3 is connected with a conveying assembly 4 for conveying energy-saving cement and increasing the cooling area of the energy-saving cement discharged from the warehouse; one side of the cooling cylinder 1 is provided with a controller 5 for controlling electrical equipment; one end of the cooling cylinder 1 is provided with a discharge hopper 6 for outputting cooled energy-saving cement.

Example one

Referring to fig. 1 to 6, for the cooling mechanism 3, the cooling mechanism 3 includes a collecting pipe 301 disposed at one end of the conveying bucket 2, and one end of the collecting pipe 301 is provided with collecting holes 11 at equal intervals; an input pipe 302 is arranged on one side of the collecting pipe 301, a conveying pump 303 is arranged at one end of the input pipe 302, a collecting box 7 is arranged on the input pipe 302 close to the cooling cylinder 1, a conveying port is formed in the collecting box 7 close to the cooling cylinder 1, and a filter screen 12 is arranged in the collecting box 7; an output pipe 304 is arranged at one end of the delivery pump 303, and when the cooling device is actually used, a cooling device can be arranged between the delivery pump 303 and the output pipe 304, so that the cooling effect can be further ensured; conveying pipes 305 are arranged on one side of the output pipe 304 at equal intervals, the conveying pipes 305 are sleeved on the surface of the cooling cylinder 1, a first conveying cover 306 is arranged on one side of the conveying pipes 305 close to the cooling cylinder 1, the first conveying cover 306 penetrates through the periphery of the cooling cylinder 1, the first conveying cover 306 is of a circular truncated cone structure, and a filter screen is arranged in the first conveying cover 306; the delivery assembly 4 is connected to one end of the output tube 304.

Through the above technical scheme of the utility model, when using, pour the energy-saving cement of leaving warehouse into through the delivery bucket 2, then make delivery pump 303 start through controller 5, then a plurality of collecting hole 11 on collecting pipe 301 surface is to pouring into the dust that produces and absorbing, the dust of being absorbed passes through input tube 302 and carries in collecting box 7, then carry the dust of absorbing in cooling cylinder 1 through the delivery port of collecting box 7 one side, can guarantee to carry the effect through setting up filter screen 12 in order to prevent that the dust from entering into delivery pump 303 output, it is intraductal to be carried reposition of redundant personnel to conveyer pipe 305 through output tube 304 to filtered air after that, then spray away through first transport cover 306, cool down to energy-saving cement outside.

Example two

Referring to fig. 1-6, for the conveying assembly 4, the conveying assembly 4 includes a hollow motor 401 disposed at one end of the output pipe 304, and the hollow motor 401 is disposed at one side of the cooling cylinder 1, the hollow motor 401 is 14HS42-4-D-100; one end of the hollow motor 401 penetrates through the cooling cylinder 1 and is provided with a conveying rod 402, and the conveying rod 402 is connected with the hollow motor 401 through a coupler; a conveying plate 403 is arranged on the surface of the conveying rod 402, the conveying plate 403 is of an S-shaped structure, and the conveying plate 403 is wound on the surface of the conveying rod 402; the grinding component 8 is arranged on one side of the conveying plate 403 close to the conveying rod 402, the conveying rod 402 is provided with two sections, a conveying cavity 9 is formed in the middle of one section of the conveying rod 402, equidistant output holes are formed in the conveying cavity 9 close to the conveying rod 402, and a second conveying cover 10 is arranged at one end of each output hole.

Through the above technical scheme of the utility model, when using, make when hollow motor 401 rotates that conveying rod 402 drives conveying plate 403 and rotate, carry the energy-saving cement that pulverizes, and in transportation process, break up the energy-saving cement of carrying, thereby can be with the heat radiating area increase of energy-saving cement, and then guarantee the cooling effect, and break up the messenger and pass through output tube 304 to hollow motor 401 one side carrier gas, then gas carries through thick hollow conveying rod 402, then make it cool down through the energy-saving cement of second delivery cover 10 blowout at break up and cooling cylinder 1 middle part through the pressure of delivery pump 303.

EXAMPLE III

Referring to fig. 1-6, for the grinding assembly 8, the grinding assembly 8 includes a first grinding roller 801 disposed on the conveying rod 402, one end of the first grinding roller 801 is disposed on one side of the cooling cylinder 1, a first grinding block 802 is disposed on the surface of the first grinding roller 801, a second grinding block 803 is disposed around the first grinding block 802, a second grinding roller 804 is disposed on one side of the second grinding block 803, one end of the second grinding roller 804 is disposed on one side of the cooling cylinder 1, and the first grinding roller 801 and the second grinding roller 804 are both connected to one side of the cooling cylinder 1 through bearings; the first crushing block 802 and the second crushing block 803 are both in an integrated structure with the first crushing roller 801 and the second crushing roller 804, and the first crushing block 802 and the second crushing block 803 are meshed and connected with each other; the delivery pump 303 and the hollow motor 401 are electrically connected to the controller 5 and the external power source.

Through the above technical scheme of the utility model, when using, pour the energy-saving cement that will go out of warehouse into through transport bucket 2, then make hollow motor 401 start through controller 5 and make transport rod 402 rotate, drive first crushing roller 801 and first fragment 802 of grinding after that and rotate, drive second crushing roller 804 through grinding the fragment 803 meshing with the second and rotate, pulverize the energy-saving cement that goes out of warehouse that pours into transport bucket 2 immediately, thereby can avoid the problem that partial caking problem and the cooling effect that leads to is not good to appear.

In conclusion, by means of the technical scheme of the utility model, when in use, the energy-saving cement discharged from the warehouse is poured in through the conveying bucket 2, then, when the hollow motor 401 is started by the controller 5, the feed rod 402 is rotated, and then the first crushing roller 801 and the first crushing block 802 are rotated, then the second grinding roller 804 is driven to rotate by being meshed with the second grinding block 803, and the energy-saving cement discharged from the warehouse and poured into the conveying bucket 2 is ground immediately, so that the problem of poor cooling effect caused by partial caking problem can be avoided, then, when the transfer pump 303 is started by the controller 5, then the plurality of collection holes 11 on the surface of the collection pipe 301 sucks the dust generated by the pouring, and then the sucked dust is transferred into the collection box 7 through the input pipe 302, then the sucked dust is conveyed into the cooling cylinder 1 through a conveying opening at one side of the collecting box 7, in order to prevent the dust from entering the output end of the conveying pump 303, the conveying effect can be ensured by arranging the filter screen 12, the filtered air is then delivered through the outlet duct 304, diverted into the delivery duct 305, and then sprayed out through the first delivery mask 306, the energy-saving cement is cooled, when the hollow motor 401 rotates, the conveying rod 402 drives the conveying plate 403 to rotate, the crushed energy-saving cement is conveyed and scattered in the conveying process, so that the heat dissipation area of the energy-saving cement can be increased, further ensuring the cooling effect, and the gas is delivered to one side of the hollow motor 401 through the output pipe 304 after the scattering, and then the gas is delivered through the thick hollow delivery rod 402, then the energy-saving cement in the middle of the scattering and cooling cylinder 1 is cooled by the pressure of the delivery pump 303 which is sprayed out through the second delivery cover 10.

The above description is only for the preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides an energy-saving cement cooling device that leaves warehouse, includes cooling cylinder (1), its characterized in that: a conveying hopper (2) is arranged at one end of the cooling cylinder (1), and a cooling mechanism (3) is arranged on one side, close to the cooling cylinder (1), of the conveying hopper (2); one end of the cooling mechanism (3) is connected with a conveying assembly (4), one side of the cooling cylinder (1) is provided with a controller (5), and one end of the cooling cylinder (1) is provided with a discharge hopper (6).

2. The energy-saving cement ex-warehouse cooling device according to claim 1, characterized in that the cooling mechanism (3) comprises a collecting pipe (301) arranged at one end of the conveying hopper (2), an input pipe (302) is arranged at one side of the collecting pipe (301), a conveying pump (303) is arranged at one end of the input pipe (302), and a collecting box (7) is arranged at the position, close to the cooling cylinder (1), of the input pipe (302).

3. The energy-saving cement ex-warehouse cooling device according to claim 2, characterized in that an output pipe (304) is arranged at one end of the delivery pump (303), an equidistant delivery pipe (305) is arranged on one side of the output pipe (304), the surface of the cooling cylinder (1) is sleeved with the delivery pipe (305), a first delivery cover (306) is arranged on one side of the delivery pipe (305) close to the cooling cylinder (1), and the delivery assembly (4) is connected with one end of the output pipe (304).

4. The energy-saving cement ex-warehouse cooling device according to claim 3, wherein the conveying assembly (4) comprises a hollow motor (401) arranged at one end of the output pipe (304), a conveying rod (402) is arranged at one end of the hollow motor (401) penetrating through the cooling cylinder (1), a conveying plate (403) is arranged on the surface of the conveying rod (402), and a crushing assembly (8) is arranged on one side of the conveying plate (403) close to the conveying rod (402).

5. The energy-saving cement ex-warehouse cooling device according to claim 4, wherein a conveying cavity (9) is formed in the middle of the conveying rod (402), equidistant output holes are formed in the conveying cavity (9) close to the conveying rod (402), and a second conveying cover (10) is arranged at one end of each output hole.

6. The energy-saving cement warehouse-out cooling device according to claim 4, characterized in that the grinding assembly (8) comprises a first grinding roller (801) arranged on the conveying rod (402), one end of the first grinding roller (801) is arranged on one side of the cooling cylinder (1), and the surface of the first grinding roller (801) is provided with first grinding blocks (802) with equal distance.

7. The energy-saving cement ex-warehouse cooling device according to claim 6, characterized in that the first crushing block (802) is provided with a second crushing block (803) at equal intervals, one side of the second crushing block (803) is provided with a second crushing roller (804), and one end of the second crushing roller (804) is arranged on one side of the cooling cylinder (1).

8. The energy-saving cement ex-warehouse cooling device according to claim 2, wherein one end of the collecting pipe (301) is provided with collecting holes (11) at equal intervals, the collecting box (7) is provided with a conveying port close to the cooling cylinder (1), and a filter screen (12) is arranged in the collecting box (7).

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