CN217037825U - Dampproofing treatment facility of yellow river hydraulic and hydroelectric engineering equipment - Google Patents

Abstract

The utility model provides a moisture-proof treatment device for yellow river hydraulic and hydroelectric engineering equipment, which relates to the technical field of hydraulic equipment and comprises the following components: a box body and an auxiliary part; the box body is of a rectangular box-shaped structure, and two bearing blocks are fixedly connected in the box body through bolts; mounting plates are arranged on the two bearing blocks, and equipment elements are arranged on the mounting plates. Because the stress wheel is arranged on the rotating shaft, and the rotating shaft and the impeller are in a rotating state when the airflow is in contact with the stress wheel, the wind power cooling of equipment elements is realized; because of being connected with the spray tube on the box, and the spray tube head end is connected with collects the mouth to the spray tube tail end is adjusted well with the atress wheel position, thereby collects wind-force and spouts the rotation that can realize the impeller to the hand of atress wheel through the spray tube when collecting the mouth, has solved the diffusion that the temperature that current device component produced can not be fine when using, condenses into the drop of water easily, influences the problem of equipment safety.

Description

Dampproofing treatment facility of yellow river hydraulic and hydroelectric engineering equipment

Technical Field

The utility model relates to the technical field of hydraulic equipment, in particular to dampproof treatment equipment for yellow river hydraulic and hydroelectric engineering equipment.

Background

With the serious shortage of water resources and the increasing aggravation of energy crisis in China and even in the world, the river treatment is accelerated, the hydropower is developed and utilized preferentially, and the optimization configuration of the water resources becomes urgent, so that the hydraulic and hydroelectric engineering is an important infrastructure and basic industry in China; water conservancy and hydropower equipment works in a humid environment for a long time and is easily affected with damp and damaged.

However, in terms of the existing traditional damp-proof treatment equipment for hydraulic and hydroelectric engineering equipment, the temperature generated by equipment elements cannot be well diffused when the existing device is used, and the temperature is easily condensed into water drops, so that the equipment safety is affected.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a dampproof processing device for yellow river hydraulic and hydroelectric engineering equipment, which is provided with a through hole and a bulge, and can ensure that the heat dissipation basic condition of equipment elements is good through the arrangement of the through hole and the bulge;

the device is also provided with an auxiliary part, and the wind power cooling of the equipment element can be realized through natural wind power by the arrangement of the auxiliary part.

The utility model provides a dampproof processing device for yellow river hydraulic and hydroelectric engineering equipment, which specifically comprises: a box body and an auxiliary part; the box body is of a rectangular box-shaped structure, and two bearing blocks are fixedly connected in the box body through bolts; mounting plates are arranged on the two bearing blocks, and equipment elements are mounted on the mounting plates; the mounting plate is provided with through holes in a rectangular array shape, the through holes are in cylindrical hole structures, and the rectangular array shape and the through holes form a ventilation structure of the equipment element; the auxiliary part comprises pivot, impeller, atress wheel, spray tube and collection mouth, and the pivot rotates to be connected in the box.

Optionally, the bearing block is welded with protrusions in a linear array, the protrusions are of a semi-cylindrical structure, and the linear array welded with the protrusions jointly form a supporting structure of the equipment element.

Optionally, seven impellers are mounted on the rotating shaft and located 5cm below the mounting plate, and the impellers form a wind cooling structure of the equipment element.

Optionally, the rotating shaft is provided with a stressed wheel, and the rotating shaft and the impeller are in a rotating state when the airflow contacts with the stressed wheel.

Optionally, a spray pipe is connected to the box body, a collection port is connected to the head end of the spray pipe, and the tail end of the spray pipe is aligned with the stressed wheel.

Optionally, the stress wheel is provided with grooves in an annular array, and the grooves in the annular array form a friction force enhancing structure of the stress wheel.

Advantageous effects

Through the arrangement of the auxiliary part, firstly, seven impellers are arranged on the rotating shaft and positioned 5cm below the mounting plate, and the impellers form a wind power cooling structure of the equipment element, so that the wind power cooling of the equipment element can be realized when the impellers rotate;

secondly, because the stress wheel is arranged on the rotating shaft, and the rotating shaft and the impeller are in a rotating state when the airflow is in contact with the stress wheel, the wind power cooling of equipment elements is realized;

thirdly, the box body is connected with a spray pipe, the head end of the spray pipe is connected with a collecting port, and the tail end of the spray pipe is aligned with the stressed wheel, so that when wind power is collected by the collecting port and sprayed to the stressed wheel through the spray pipe, the rotation of the impeller can be realized;

through the arrangement of the mounting plate, the through holes and the bulges, firstly, the mounting plate is placed on the two bearing blocks, and equipment elements are arranged on the mounting plate; the mounting plate is provided with through holes in a rectangular array shape, the through holes are in cylindrical hole structures, and the rectangular array shape and the through holes form a ventilation structure of the equipment element together, so that the ventilation effect of the equipment element can be ensured;

secondly, the bearing block is welded with the bulges in a linear array shape, the bulges are of a semi-cylindrical structure, and the bulges are welded in the linear array shape to jointly form a supporting structure of the equipment element, so that the ventilation effect of the bottom of the equipment element can be ensured.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings in the following description relate to only some embodiments of the utility model and are not intended to limit the utility model.

In the drawings:

fig. 1 is a schematic front view of the present invention.

Fig. 2 is a schematic axial view of the case of the present invention.

Fig. 3 is a left side view schematic diagram of the present invention.

Fig. 4 is an enlarged schematic view of the structure at a in fig. 3 according to the present invention.

List of reference numerals

1. A box body; 101. a bearing block; 102. mounting a plate; 103. a through hole; 104. a protrusion; 2. an auxiliary part; 201. a rotating shaft; 202. an impeller; 203. a stress wheel; 204. a nozzle; 205. a collection port.

Detailed Description

In order to make the objects, aspects and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference symbols in the various drawings indicate like elements.

Example (b): please refer to fig. 1 to fig. 4:

the utility model provides a dampproof processing device for yellow river hydraulic and hydroelectric engineering equipment, which comprises: a box body 1 and an auxiliary part 2;

the box body 1 is of a rectangular box-shaped structure, and two bearing blocks 101 are fixedly connected in the box body 1 through bolts;

the auxiliary part 2 is composed of a rotating shaft 201, an impeller 202, a stress wheel 203, a spray pipe 204 and a collecting port 205, and the rotating shaft 201 is rotatably connected in the box body 1.

In addition, according to the embodiment of the present invention, as shown in fig. 2, the mounting plate 102 is placed on the two support blocks 101, and the equipment components are mounted on the mounting plate 102;

the mounting plate 102 is provided with through holes 103 in a rectangular array shape, the through holes 103 are in a cylindrical hole structure, and the rectangular array shape and the through holes 103 jointly form a ventilation structure of the equipment element, so that the ventilation effect of the equipment element can be ensured.

In addition, according to the embodiment of the present invention, as shown in fig. 2, the protrusions 104 are welded on the supporting block 101 in a linear array, and the protrusions 104 are in a semi-cylindrical structure, and the linear array of the welded protrusions 104 together form a supporting structure of the device component, so that the ventilation effect of the bottom of the device component can be ensured.

In addition, according to the embodiment of the present invention, as shown in fig. 2, seven impellers 202 are installed on the rotating shaft 201, and the impellers 202 are located 5cm below the installation plate 102, and the impellers 202 constitute a wind cooling structure of the equipment component, so that the wind cooling of the equipment component can be realized when the impellers 202 rotate.

In addition, according to the embodiment of the present invention, as shown in fig. 2, the force-bearing wheel 203 is installed on the rotating shaft 201, and the rotating shaft 201 and the impeller 202 are in a rotating state when the airflow contacts with the force-bearing wheel 203, so that the wind cooling of the equipment components is also realized.

In addition, according to the embodiment of the present invention, as shown in fig. 2 and 4, a nozzle 204 is connected to the casing 1, a collection port 205 is connected to a head end of the nozzle 204, and a rear end of the nozzle 204 is aligned with the force receiving wheel 203, so that when wind is collected by the collection port 205 and is sprayed to the force receiving wheel 203 through the nozzle 204, the rotation of the impeller 202 can be achieved.

In addition, according to the embodiment of the present invention, as shown in fig. 4, the stress wheel 203 is provided with the grooves in an annular array, and the grooves in the annular array form a friction force enhancing structure of the stress wheel 203, so as to ensure the rotation efficiency of the rotating shaft 201.

The specific use mode and function of the embodiment are as follows:

when the equipment elements are installed, the installation plates 102 are placed on the two bearing blocks 101, and the equipment elements are installed on the installation plates 102; the mounting plate 102 is provided with through holes 103 in a rectangular array shape, the through holes 103 are in cylindrical hole structures, and the rectangular array shape and the through holes 103 jointly form a ventilation structure of the equipment element, so that the ventilation effect of the equipment element can be ensured; the bulges 104 are welded on the bearing block 101 in a linear array manner, the bulges 104 are in a semi-cylindrical structure, and the bulges 104 welded in a linear array manner jointly form a supporting structure of the equipment element, so that the ventilation effect of the bottom of the equipment element can be ensured;

in the use process, the seven impellers 202 are arranged on the rotating shaft 201, the impellers 202 are positioned 5cm below the mounting plate 102, and the impellers 202 form a wind power cooling structure of equipment elements, so that the wind power cooling of the equipment elements can be realized when the impellers 202 rotate; because the stress wheel 203 is arranged on the rotating shaft 201, and the rotating shaft 201 and the impeller 202 are in a rotating state when the airflow contacts with the stress wheel 203, the wind power cooling of equipment elements is realized; and because the jet pipe 204 is connected on the box body 1, the head end of the jet pipe 204 is connected with the collection port 205, and the tail end of the jet pipe 204 is aligned with the stress wheel 203, the rotation of the impeller 202 can be realized when the wind power is collected by the collection port 205 and is jetted to the stress wheel 203 through the jet pipe 204.

Finally, it should be noted that, when describing the positions of the components and the matching relationship therebetween, the present invention is usually illustrated by one/a pair of components, however, it should be understood by those skilled in the art that such positions, matching relationship, etc. are also applicable to other/other pairs of components.

The above description is intended to be illustrative of the present invention and not to limit the scope of the utility model, which is defined by the claims appended hereto.

Claims (6)

1. Dampproofing treatment facility of yellow river hydraulic and hydroelectric engineering equipment, its characterized in that includes: a box body (1) and an auxiliary part (2); the box body (1) is of a rectangular box-shaped structure, and two bearing blocks (101) are fixedly connected in the box body (1) through bolts; mounting plates (102) are placed on the two bearing blocks (101), and equipment elements are mounted on the mounting plates (102); the mounting plate (102) is provided with through holes (103) in a rectangular array shape, the through holes (103) are in cylindrical hole-shaped structures, and the rectangular array shape and the through holes (103) jointly form a ventilation structure of equipment elements; the auxiliary part (2) consists of a rotating shaft (201), an impeller (202), a stress wheel (203), a spray pipe (204) and a collecting port (205), and the rotating shaft (201) is rotatably connected in the box body (1).

2. The yellow river hydraulic and hydroelectric engineering equipment moisture-proof treatment equipment as claimed in claim 1, wherein: the bearing block (101) is welded with the bulges (104) in a linear array manner, the bulges (104) are of a semi-cylindrical structure, and the bulges (104) welded in the linear array manner jointly form a supporting structure of equipment elements.

3. The yellow river hydraulic and hydroelectric engineering equipment moisture-proof treatment equipment as claimed in claim 1, wherein: seven impellers (202) are mounted on the rotating shaft (201), the impellers (202) are located 5cm below the mounting plate (102), and the impellers (202) form a wind power cooling structure of equipment elements.

4. The yellow river hydraulic and hydroelectric engineering equipment moisture-proof treatment equipment as claimed in claim 1, wherein: the rotating shaft (201) is provided with a stress wheel (203), and the rotating shaft (201) and the impeller (202) are in a rotating state when the airflow is in contact with the stress wheel (203).

5. The yellow river hydraulic and hydroelectric engineering equipment moisture-proof treatment equipment as claimed in claim 1, wherein: the box body (1) is connected with a spray pipe (204), the head end of the spray pipe (204) is connected with a collecting port (205), and the tail end of the spray pipe (204) is aligned with the stress wheel (203).

6. The yellow river hydraulic and hydroelectric engineering equipment moisture-proof treatment equipment as claimed in claim 1, wherein: the stress wheel (203) is provided with grooves in an annular array shape, and the grooves in the annular array shape jointly form a friction force enhancing structure of the stress wheel (203).

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