CN113532045A - Wind energy heating drying equipment - Google Patents

Abstract

The invention discloses wind energy heating drying equipment which structurally comprises an equipment box, a controller, a thermometer and a dust cover, wherein the surface of the equipment box is welded and connected with the tail end of the controller, the left side of the controller is in clearance fit with the dust cover, the dust cover is integrally fixed with the surface of the equipment box through bolts, the surface of the equipment box is integrally embedded and connected with the thermometer, the equipment box comprises a heat preservation cabinet, a heat exchange box, a suction fan and a heat pump, the left end of the heat preservation cabinet is welded and connected with the right side of the heat exchange box, the front end of the heat exchange box is movably matched with the interior of the heat pump, and the right side of the heat pump is in clearance fit with the heat preservation cabinet. Meanwhile, the problems that external heat energy cannot be promoted and the drying time is increased are effectively avoided.

Description

Wind energy heating drying equipment

Technical Field

The invention relates to the field of wind energy, in particular to wind energy heating drying equipment.

Background

The process of converting wind energy into heat energy by using a wind power machine and a heating device is called wind energy heating, which simply means that the wind energy heats the required equipment to generate heat energy, and wind energy heating is widely applied in the drying industry;

however, the prior art has the following defects: the current wind energy drying equipment that generates heat owing to realize generating heat through wind energy and carry out the energy supply to the drying-machine for the in-process of using is dried the object because need release heat, and inside circulating pipe withdraws its hot-blast that blows off for the circulation easily when wind energy blows to the heat energy pipe, thereby leads to external heat energy to obtain not promoting, and then causes the stoving effect to reduce, increase consuming time.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide wind energy heating drying equipment to solve the problems that in the prior art, the drying machine is powered by wind energy, so that objects are dried by releasing heat in the use process, and when wind energy blows a heat energy pipe, hot air blown out by an internal circulating pipe is easily recycled by the internal circulating pipe, so that the external heat energy cannot be improved, the drying effect is reduced, and the consumed time is increased.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a wind energy drying equipment that generates heat, its structure includes equipment box, controller, thermometer, dust cover, equipment box surface and the terminal welded connection of controller, the whole clearance fit of controller left side and dust cover, the whole bolt fastening with equipment box surface of dust cover, equipment box surface and the whole embedded connection of thermometer, equipment box includes heat preservation cabinet, heat transfer case, suction fan, heat pump, heat preservation cabinet left end and heat transfer case right side welded connection, the inside clearance fit of heat transfer case front end and heat pump, the whole clearance fit of heat pump right side and heat preservation cabinet, the whole welded connection of heat transfer case left end and suction fan.

The invention is further improved, the heat preservation cabinet comprises a circulating pipe, a heat preservation layer, support columns and air inlet and outlet grooves, the left end of the circulating pipe is fixedly connected with the tail ends of the air inlet and outlet grooves in an embedded mode, the whole air inlet and outlet grooves are connected with the surface of the heat preservation layer in a clamped mode, the inner side of the heat preservation layer is in clearance fit with the whole circulating pipe, the lower end of the circulating pipe is fixedly connected with the surface of the circulating pipe in an embedded mode, the circulating pipe is distributed in the heat preservation layer, the lower surface of the circulating pipe is fixedly connected with the top ends of the support columns in an embedded mode, and the two sides of the circulating pipe are fixedly connected with the tail ends of the air inlet and outlet grooves in an embedded mode.

The invention is further improved, the circulating pipe comprises a diversion trench, a pipe body and a heating wire, the diversion trench is integrally and fixedly connected with the left end and the right end of the pipe body in an embedded mode, the inner wall of the pipe body is connected with the two ends of the heating wire in a welded mode, the outer end of the heating wire is in clearance fit with the diversion trench integrally, the heating wire is distributed inside the pipe body, the two ends of the heating wire are connected with the inner wall of the pipe body in a welded mode, and the heating wire and the diversion trench form clearance fit.

The invention is further improved, the diversion trench comprises a fixed frame, an air inlet, an air outlet and a swing barrier strip, the bottom of the fixed frame is hinged with the top end of the swing barrier strip, the outer side of the swing barrier strip is movably matched with the inside of the air outlet, the inner side of the air outlet is in clearance fit with the air inlet integrally, and two heating wires are respectively hinged at the lower end of the fixed frame and movably matched with the air inlet and the air outlet.

The invention is further improved, the air inlet and outlet groove comprises a heat supply groove, pulley rails and a protective cover, the whole heat supply groove is connected with the inside of the protective cover in an embedded mode, the center of the protective cover is connected with the pulley rails in an embedded mode, the surfaces of the pulley rails are in sliding fit with the inner side of the heat supply groove, two pulley rails are arranged and distributed in the center of the protective cover to be connected with the center of the protective cover in an embedded mode, and the two sides of the pulley rails are in sliding fit with the inner side of the heat supply groove.

The invention is further improved, the heat supply groove comprises a diffusion plate, a swing seat, a circulation cavity and a flow dividing strip, the bottom of the diffusion plate is connected with the swing seat in a clamping mode, the interior of the swing seat is hinged to the top end of the flow dividing strip, the whole flow dividing strip is movably matched with the interior of the circulation cavity, the top end of the circulation cavity is movably matched with the interior of the diffusion plate, the flow dividing strip is distributed in the circulation cavity, and heat energy passing through the circulation cavity is divided through the hinged connection of the swing seat.

The diffusion plate is further improved, the tail end of the guide plate is hinged to the surface of the plate body, the surface of the plate body is fixedly embedded to the tail end of the support spring strip, the top end of the support spring strip is movably clamped to the surface of the guide plate, two groups of five guide plates are arranged, the five guide plates are evenly distributed on the surface of the plate body and are hinged to the plate body, and two side walls of the guide plates are movably clamped to the support spring strip.

The invention is further improved, the guide plate comprises a clamping groove, an inclined plate block, an arc swinging seat and an anti-falling ring, the whole clamping groove is fixedly connected with the surface of the inclined plate block in an embedded mode, the tail end of the inclined plate block is fixedly connected with the top end of the arc swinging seat, the whole arc swinging seat is in sliding fit with the inside of the anti-falling ring, the upper end of the anti-falling ring is in clearance fit with the whole inclined plate block, the lower end of the whole arc swinging seat is in an arc state and is matched with the anti-falling ring to perform nested swinging, and the inclined plate block is indirectly driven to move.

Advantageous effects

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

1. the heat exchanger is matched with the heat pump through the suction fan to generate heat, so that heat energy is continuously conveyed to an object to be dried through the circulating pipe, the swing barrier strip can be opened only under the condition of downwind with the aid of the flow guide groove, the problem that hot air blown out by the circulating pipe is recycled for circulation is solved, and the problems that external heat energy cannot be improved and drying time is increased are effectively avoided.

2. According to the invention, the heat supply groove is used for continuously supplying heat to the drying object, the blowing direction is preliminarily changed under the auxiliary cooperation of the diversion strip and the swing seat, so that the follow-up guide plate is changed at different angles on the anti-drop ring and the arc swing seat, hot air is continuously conveyed outwards from different angles, the peripheral diffusion capacity is improved in the using process, the diffusion heating area of the equipment is effectively accelerated, and the internal drying effect is improved in a phase-changing manner.

Drawings

Fig. 1 is a schematic structural diagram of a wind energy heating drying device of the present invention.

Fig. 2 is a schematic top view of the equipment box of the present invention.

FIG. 3 is a schematic top view of the thermal insulation cabinet of the present invention.

FIG. 4 is a schematic view showing the internal structure of the circulation tube of the present invention.

Fig. 5 is a schematic view of the internal structure of the flow guide groove of the present invention.

FIG. 6 is a schematic view of the internal structure of the air inlet/outlet duct of the present invention.

FIG. 7 is a schematic view of the internal structure of the heat supplying tank of the present invention.

FIG. 8 is a schematic view of the internal structure of the diffuser plate according to the present invention.

Fig. 9 is a schematic view of the internal structure of the guide plate of the present invention.

In the figure: an equipment box-1, a controller-2, a thermometer-3, a dust cover-4, a heat preservation cabinet-11, a heat exchange box-12, a suction fan-13, a heat pump-14, a circulating pipe-111, a heat preservation layer-112, a support column-113, an air inlet and outlet groove-114, a diversion groove-a 1, a pipe body-a 2, a heating wire-a 3, a fixed frame-a 11 and an air inlet-a 12, air outlet-a 13, swing bar-a 14, heat supply groove-b 1, pulley rail-b 2, protective cover-b 3, diffusion plate-b 11, swing seat-b 12, circulation cavity-b 13, shunt bar-b 14, guide plate-c 1, plate body-c 2, support spring bar-c 3, clamping groove-c 11, inclined plate block-c 12, arc swing seat-c 13 and anti-slip ring-c 14.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, not all embodiments of the present invention, and all other embodiments obtained by those skilled in the art without any inventive work based on the embodiments of the present invention belong to the protection scope of the present invention.

The invention is further described below with reference to the accompanying drawings:

example 1

As shown in figures 1 to 5:

its structure includes equipment box 1, controller 2, thermometer 3, dust cover 4, 1 surface of equipment box and 2 terminal welded connection of controller, 2 left sides of controller and the whole clearance fit of dust cover 4, the whole 1 surface bolt fastening of dust cover 4 and equipment box, 1 surface of equipment box and the whole built-in connection of thermometer 3, equipment box 1 includes heat preservation cabinet 11, heat transfer case 12, suction fan 13, heat pump 14, 11 left ends of heat preservation cabinet and the 12 right sides welded connection of heat transfer case, the inside clearance fit of 12 front ends of heat transfer case and heat pump 14, the 14 right sides of heat pump and the 11 whole clearance fit of heat preservation cabinet, the 12 left ends of heat transfer case and the whole welded connection of suction fan 13.

Wherein, heat preservation cabinet 11 includes circulating pipe 111, heat preservation 112, support column 113, business turn over wind groove 114, circulating pipe 111 left end is connected with business turn over wind groove 114 end embedded solid, it is whole to be connected with heat preservation 112 surface block to advance wind groove 114, the whole clearance fit of heat preservation 112 inboard and circulating pipe 111, circulating pipe 111 lower extreme and circulating pipe 111 surface embedded solid are connected, circulating pipe 111 distributes inside heat preservation 112, and the lower surface is connected with the embedded solid on support column 113 top, and both sides and business turn over wind groove 114 end embedded solid are connected, and wherein advance the wind groove 114 and be favorable to the heat after the wind energy generates heat to circulate inside the body to blow at cooperation wind-force and reach the outside object output heat that dries of continuation and dry, reduce the equipment power consumption.

The circulation pipe 111 comprises a diversion trench a1, a pipe body a2 and a heating wire a3, wherein the diversion trench a1 is integrally connected with the left end and the right end of the pipe body a2 in a fixed manner, the inner wall of the pipe body a2 is connected with the two ends of the heating wire a3 in a welded manner, the outer end of the heating wire a3 is in clearance fit with the diversion trench a1 integrally, the heating wire a3 is distributed inside the pipe body a2, the two ends of the heating wire a3 are connected with the inner wall of the pipe body a2 in a welded manner, and the diversion trench a1 is in clearance fit with the heating wire a3, so that the temperature of the internal heat can be kept at a designated height, and the output heat can be kept consistent through the assistance of the heating wire a 3.

The diversion trench a1 comprises a fixed frame a11, an air inlet a12, an air outlet a13 and a swing bar a14, the bottom of the fixed frame a11 is hinged to the top end of the swing bar a14, the outer side of the swing bar a14 is movably matched with the inside of the air outlet a13, the inner side of the air outlet a13 is in clearance fit with the whole air inlet a12, two heating wires a3 are arranged and are respectively hinged to the lower end of the fixed frame a11 and movably matched with the air inlet a12 and the air outlet a13, the swing bar a14 is favorable for blocking heat at low temperature outside from entering equipment, and the heat is intelligently blown and reversed by downwind, so that the heat inside the pipe body is conveyed outwards after being unfolded, the heat of backflow outside is blocked, and the heat of the outside is promoted.

The specific working principle is as follows:

the invention starts the operation of the equipment through the controller 2 on the surface of the equipment box 1, so that the suction fan 13 in the dust cover 4 starts to guide wind energy, thereby heating the circulating pipe 111 embedded and fixed on the support column 113 in the heat insulation layer 112 in the heat insulation cabinet 11 under the matching of the heat exchange direction 12 and the heat pump 14, after heating, the thermometer 3 displays the internal temperature, so that the wind power is blown into the diversion trench a1 from the wind inlet and outlet trench 114 under the matching of the wind energy, the heating wire a3 in the matching tube body a2 continuously dries the external drying object, when the wind power blows the heat energy from the wind inlet a12 to the wind outlet c13, the swing bar a14 is blown upwards under the hinged matching of the fixed frame a11 due to the principle of the downwind, so that the other end is still in a closed state due to the set placing position, thereby changing the heat energy backflow problem of the circulating pipe 111 with the heat exchange temperature difference, the suction fan 13 heats under the matching of the heat pump box 12 and the heat pump 14, therefore, heat energy is continuously conveyed to the outside drying object through the circulating pipe 111, so that the auxiliary lower swing barrier a14 of the diversion trench a1 can only be opened under the condition of downwind, the problem that the circulating pipe 111 recycles hot air blown out of the circulating pipe for circulation is solved, and the problems that the external heat energy cannot be lifted and the drying time is increased are effectively avoided.

Example 2:

as shown in fig. 6 to 9:

wherein, it includes heat supply groove b1, pulley rail b2, protection casing b3 to advance air outlet 114, heat supply groove b1 is whole to be connected with the inside nested of protection casing b3, protection casing b3 center is connected with pulley rail b2 is whole to be embedded solid, pulley rail b2 surface and the inboard sliding fit of heat supply groove b1, pulley rail b2 is equipped with two, distributes and carries out embedded solid connection at the central point of protection casing b3 and its protection casing b3 center, and both sides and heat supply groove b1 are inboard to carry out sliding fit, and wherein heat supply groove b1 is favorable to adjusting under pulley rail b 2's supplementary to change inside to the interval on top, thereby can be better make its inside heat outwards output, thereby accelerate the object to dry.

The heat supply groove b1 comprises a diffusion plate b11, a swing seat b12, a flow distribution cavity b13 and a flow distribution strip b14, the bottom of the diffusion plate b11 is integrally clamped and connected with a swing seat b12, the inside of the swing seat b12 is hinged and connected with the top end of the flow distribution strip b14, the whole flow distribution strip b14 is movably matched with the inside of the flow distribution cavity b13, the top end of the flow distribution cavity b13 is movably matched with the inside of the diffusion plate b11, the flow distribution strip b14 is distributed inside the flow distribution cavity b13, and the heat energy passing through the flow distribution cavity b13 is distributed through the hinged connection of the swing seat b12, wherein the flow distribution strip b14 is favorable for changing the angle of the internal hot air diffused outwards, so that the diffusion plate b11 can blow the hot air around, and the diffusion heating area of the equipment is increased.

The diffusion plate b11 comprises a guide plate c1, a plate body c2 and a support spring bar c3, the tail end of the guide plate c1 is hinged to the surface of the plate body c2, the surface of the plate body c2 is fixedly connected to the tail end of the support spring bar c3, the top end of the support spring bar c3 is movably clamped with the surface of a guide plate c1, two groups of the guide plate c1 are arranged, five guide plates are directly arranged in each group, are evenly distributed on the surface of the plate body c2 and are hinged to the plate body c2, and two side walls are movably clamped with the support spring bar c3, wherein the support spring bar c3 is beneficial to supporting the guide plate c1 in the swinging process, so that the air opening of the plate body is prevented from being blocked due to an overlarge swinging angle through supporting force, and the problem that wind cannot blow to the periphery is avoided.

The guide plate c1 comprises a clamping groove c11, an inclined plate c12, an arc swing seat c13 and an anti-falling ring c14, the clamping groove c11 is integrally and fixedly connected with the surface of the inclined plate c12, the tail end of the inclined plate c12 is fixedly connected with the top end of the arc swing seat c13, the arc swing seat c13 is integrally and slidably matched with the inside of the anti-falling ring c14, the upper end of the anti-falling ring c14 is in overall clearance fit with the inclined plate c12, the lower end of the arc swing seat c13 is in an arc state and is matched with the anti-falling ring c14 to perform nested swinging, the inclined plate c12 is indirectly driven to displace, and the arc swing seat c13 is beneficial to driving the inclined plate c12 to perform different angle replacement under the auxiliary fit of the anti-falling ring c14, so that the diffused wind direction is changed while working, the peripheral diffusion capacity is improved in the use process, and the internal drying effect is improved.

The specific working principle is as follows:

the invention adjusts the air-out space of the heat-supplying slot b1 through the pulley rail b2 in the shield b3, so that the hot air flows through the circulation chamber b13 when air-out, the diffuser plate b11 is assisted to change the blow-out angle and diffusion area of the drying hot air by matching with the shunt strip b14 hinged and movable by the swing seat b12, so that the guide plate c1 is blown after the preliminary dispersion of the shunt strip b14, so that the falling-off preventing ring c14 hinged and connected in the plate body c2 changes the orientation of the inclined plate c12 under the swing of the arc swing seat c13, meanwhile, the branch spring strip c3 clamped by the clamp slot c11 supports the plate surface, the over-large inclination angle is prevented, the closing phenomenon directly occurs, the inclined plate c12 is changed with different angles under the continuous blowing, the hot air is blown to blow each angle of the drying object, thereby accelerating the internal drying effect, the invention continuously blows the drying object through the heat-supplying slot b1, the auxiliary blowing direction of the shunt strip b14 and the swing seat 12 is changed, make follow-up deflector c1 carry out the change of different angles on anticreep ring c14 and arc pendulum seat b13, with hot-blast outwards transport continuously from different angles, improve diffusion ability all around in the use, the effectual equipment diffusion heated area that has accelerated to the change improves inside stoving effect.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein; any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (8)

1. The utility model provides a wind energy drying equipment that generates heat, its structure includes equipment box (1), controller (2), thermometer (3), dust cover (4), equipment box (1) surface and the terminal welded connection of controller (2), the whole clearance fit of controller (2) left side and dust cover (4), dust cover (4) are whole with equipment box (1) surface bolt fastening, equipment box (1) surface is connected its characterized in that with thermometer (3) whole the inlaying:

equipment box (1) is including heat preservation cabinet (11), heat transfer case (12), suction fan (13), heat pump (14), heat preservation cabinet (11) left end and heat transfer case (12) right side welded connection, heat transfer case (12) front end and heat pump (14) inside clearance fit, heat pump (14) right side and heat preservation cabinet (11) whole clearance fit, heat transfer case (12) left end and suction fan (13) whole welded connection.

2. The wind energy heating drying equipment according to claim 1, characterized in that: heat preservation cabinet (11) are including circulating pipe (111), heat preservation (112), support column (113), business turn over wind groove (114), circulating pipe (111) left end is connected with business turn over wind groove (114) end embedded solid, business turn over wind groove (114) is whole to be connected with heat preservation (112) surface block, heat preservation (112) inboard and the whole clearance fit of circulating pipe (111), circulating pipe (111) lower extreme and circulating pipe (111) surface embedded solid are connected.

3. The wind energy heating drying equipment according to claim 2, characterized in that: the circulating pipe (111) comprises a diversion trench (a1), a pipe body (a2) and a heating wire (a3), wherein the diversion trench (a1) is integrally connected with the left end and the right end of the pipe body (a2) in a fixed mode, the inner wall of the pipe body (a2) is connected with the two ends of the heating wire (a3) in a welded mode, and the outer end of the heating wire (a3) is in clearance fit with the diversion trench (a1) integrally.

4. The wind energy heating drying equipment according to claim 3, characterized in that: the guiding gutter (a1) includes mount (a11), air intake (a12), air outlet (a13), pendulum fender strip (a14), mount (a11) bottom is connected with pendulum fender strip (a14) top is articulated, pendulum fender strip (a14) outside and air outlet (a13) inside clearance fit, air outlet (a13) inboard and the whole clearance fit of air intake (a 12).

5. The wind energy heating drying equipment according to claim 2, characterized in that: advance air outlet groove (114) including heat supply groove (b1), pulley rail (b2), protection casing (b3), heat supply groove (b1) whole and protection casing (b3) inside nested connection, protection casing (b3) center is connected with pulley rail (b2) whole embedded fixation, pulley rail (b2) surface and heat supply groove (b1) inboard sliding fit.

6. The wind energy heating drying equipment according to claim 5, characterized in that: the heat supply groove (b1) comprises a diffusion plate (b11), a swing seat (b12), a circulation cavity (b13) and a flow distribution strip (b14), the bottom of the diffusion plate (b11) is integrally connected with the swing seat (b12) in a clamping mode, the interior of the swing seat (b12) is hinged to the top end of the flow distribution strip (b14), the flow distribution strip (b14) is integrally matched with the interior of the circulation cavity (b13) in a movable mode, and the top end of the circulation cavity (b13) is matched with the interior of the diffusion plate (b11) in a movable mode.

7. The wind energy heating drying equipment according to claim 6, wherein: the diffusion plate (b11) comprises a guide plate (c1), a plate body (c2) and a support spring bar (c3), wherein the tail end of the guide plate (c1) is hinged with the surface of the plate body (c2), the surface of the plate body (c2) is fixedly embedded with the tail end of the support spring bar (c3), and the top end of the support spring bar (c3) is movably clamped with the surface of the guide plate (c 1).

8. The wind energy heating drying equipment according to claim 7, characterized in that: guide plate (c1) include draw-in groove (c11), incline board (c12), arc pendulum seat (c13), anticreep ring (c14), draw-in groove (c11) is whole to be connected with inclining board (c12) surface is embedded firmly, incline board (c12) end and arc pendulum seat (c13) top are embedded firmly and are connected, arc pendulum seat (c13) is whole and anticreep ring (c14) inside sliding fit, anticreep ring (c14) upper end and the whole clearance fit of inclining board (c 12).

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