CN220084204U - Distributed power supply power generation environment temperature real-time monitoring equipment - Google Patents

Abstract

The utility model discloses a real-time monitoring device for the power generation environment temperature of a distributed power supply, and relates to the technical field of monitoring of the power generation environment temperature of the distributed power supply. The device comprises a device host, wherein the bottom of the device host is connected with a group of side-by-side temperature monitoring assemblies, and each temperature monitoring assembly is electrically connected with a control module in the device host; and the temperature monitoring assembly comprises temperature sensors, connecting blocks and alarm lamps, wherein each temperature sensor is fixed with a connecting block at the detection end, and one side of each connecting block is fixed with an alarm lamp. The utility model is provided with a group of temperature monitoring components, which can monitor at multiple positions simultaneously in real time, each temperature monitoring component is provided with the alarm lamp, once the temperature of a certain position is abnormal, the alarm lamp at the position can independently send out an abnormal signal, and in addition, the equipment host is provided with the heat dissipation component, thereby achieving the purpose of dissipating heat for the power supply environment around the equipment host.

Description

Distributed power supply power generation environment temperature real-time monitoring equipment

Technical Field

The utility model belongs to the technical field of distributed power supply power generation environment temperature monitoring, and particularly relates to a distributed power supply power generation environment temperature real-time monitoring device.

Background

At present, regional electric wire netting in many provinces and cities actively inserts distributed power supply, uses distributed power supply electricity generation to need consider ambient temperature factor, generally can carry out real-time supervision to distributed power supply electricity generation ambient temperature, and current temperature monitoring equipment kind is more, and is common like current publication, CN 10338916-discloses a temperature monitoring equipment, is provided with box, wireless controller and a plurality of temperature monitoring point in the disclosure, including placing box, display, a plurality of shift knob and a plurality of temperature sensor on the box, place the box and be located one side of box, just place the box and be one end up open-ended box body, it has real-time temperature and temperature change curve to show on the display, temperature monitoring point is equipped with metal chip, shift knob, metal chip with temperature sensor is the one-to-one and joins in marriage, although can the multiposition monitoring. The following disadvantages still exist:

1. the existing monitoring equipment does not have a temperature abnormality reminding structure during multi-position monitoring, so that a user cannot know which position is abnormal in environmental temperature in time.

2. The existing monitoring equipment does not have a heat dissipation structure, and is inconvenient to dissipate heat for the power supply environment around the host computer of the monitoring equipment.

Therefore, there is an urgent need in the market for improved techniques to solve the above problems.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the utility model and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the utility model and in the title of the utility model, which may not be used to limit the scope of the utility model.

The present utility model has been made in view of the above-described problems.

Therefore, the utility model aims to provide a distributed power supply power generation environment temperature real-time monitoring device.

In order to solve the technical problems, the utility model provides the following technical scheme: the distributed power supply power generation environment temperature real-time monitoring device comprises a device host, wherein the bottom of the device host is connected with a group of temperature monitoring assemblies side by side, and each temperature monitoring assembly is electrically connected with a control module in the device host; and the temperature monitoring assembly comprises temperature sensors, connecting blocks and alarm lamps, wherein each temperature sensor is fixed with a connecting block at the detection end, and one side of each connecting block is fixed with an alarm lamp.

Further, a display screen is fixed at the upper position of the front of the equipment host, and a mounting groove is formed at the lower position of the equipment host.

Furthermore, edge grooves are formed in the edges of the front face and the back face of the mounting groove, and annular rubber pads are fixed on the inner walls of the edge grooves.

Furthermore, the blind doors are clamped in the side grooves at two sides of the mounting groove, and the blind doors are tightly attached to the rubber pads in the side grooves.

Further, the inside swing joint of mounting groove has the radiator unit, the radiator unit includes mounting bracket, bearing and fan structure, mounting bracket top and bottom are all connected with the roof and the diapire of mounting groove through the bearing, the intermediate position of mounting bracket is fixed with fan structure.

Further, the mounting frame comprises a ring plate, a cross connecting plate and a round seat plate, wherein the cross connecting plate is welded in the middle of the ring plate, and the round seat plate is welded in the middle of the back of the cross connecting plate.

Further, the fan structure comprises a motor, a connecting shaft and fan blades, wherein the shaft end of the motor is connected with the connecting shaft, and the fan blades are connected to the connecting shaft.

Further, the connecting shaft crosses the central hole of the cross connecting plate, and the motor is fixed on the inner side surface of the round seat plate.

The distributed power supply power generation environment temperature real-time monitoring device has the beneficial effects that:

1. a group of temperature monitoring components are arranged, so that the temperature monitoring components can be monitored at multiple positions simultaneously in real time, each temperature monitoring component is provided with an alarm lamp, and once the temperature at a certain position is abnormal, the alarm lamp at the position can independently send out an abnormal signal.

2. The equipment host is provided with the heat dissipation assembly, so that the air circulation speed around the equipment host can be increased, the purpose of dissipating heat for the power supply environment around the equipment host is achieved, the heat dissipation assembly is rotatable, and the wind direction of the heat dissipation assembly can be changed according to heat dissipation requirements.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

FIG. 1 is a schematic diagram of a distributed power generation environment temperature real-time monitoring device;

FIG. 2 is a schematic diagram of a device host;

FIG. 3 is a schematic diagram of a heat dissipating assembly;

FIG. 4 is a schematic structural view of the mounting bracket;

fig. 5 is a schematic structural view of a fan structure.

In the drawings, the list of components represented by the various numbers is as follows:

100. a device host; 101. a display screen; 102. a mounting groove; 103. a side groove; 104. a rubber pad; 105. a shutter door;

200. a temperature monitoring assembly; 201. a temperature sensor; 202. a connecting block; 203. an alarm lamp;

300. a heat dissipation assembly; 301. a mounting frame; 301a, a ring plate; 301b, a cross connection plate; 301c, a round seat plate; 302. a bearing; 303. a fan structure; 303a, a motor; 303b, a connecting shaft; 303c, fan blades.

Detailed Description

In order that the above-recited objects, features and advantages of the present utility model will become more readily apparent, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

Example 1

Referring to fig. 1 to 2, a first embodiment of the present utility model provides a distributed power generation environment temperature real-time monitoring device, which is provided with a set of temperature monitoring components 200, and can simultaneously monitor in real time at multiple positions, and each temperature monitoring component 200 is provided with an alarm lamp 203, once the temperature at a certain position is abnormal, the alarm lamp 203 at the position can send an abnormal signal separately.

Specifically, the device host 100, the bottom of the device host 100 is connected with a group of side-by-side temperature monitoring assemblies 200, and each temperature monitoring assembly 200 is electrically connected with a control module in the device host 100; the method comprises the steps of,

temperature monitoring assembly 200, temperature monitoring assembly 200 includes temperature sensor 201, connecting block 202 and warning light 203, and the detection end of every temperature sensor 201 all is fixed with connecting block 202, and one side of connecting block 202 is fixed with warning light 203.

Further, a display screen 101 is fixed at a position above the front surface of the device host 100, and a mounting groove 102 is provided at a position below the device host 100.

The display 101 is electrically connected to a control module in the host 100.

The operation process comprises the following steps: when the temperature monitoring device is used, a group of temperature monitoring components 200 are fixed at all positions to be monitored in a distributed power generation environment, and during the monitoring period, the temperatures at all positions are transmitted to the device host 100 in real time through the group of temperature monitoring components 200 and displayed on the display screen 101;

during monitoring, if the temperature of a certain position of the distributed power generation environment is abnormal, the temperature sensor 201 at the position immediately transmits a signal to the control module in the equipment host 100, and at the same time, the control module in the equipment host 100 drives the alarm lamp 203 at the position to individually flash to send out a signal indicating the abnormality.

Example 2

Referring to fig. 2 to 5, in a third embodiment of the present utility model, the embodiment is based on the previous embodiment, except that the device host 100 is further optimized, so that the device host 100 is provided with the heat dissipation component 300, and the air circulation speed around the device host 100 can be increased, so as to achieve the purpose of dissipating heat for the power supply environment around the device host 100.

Specifically, edge grooves 103 are formed in the edges of the front and back surfaces of the mounting groove 102, annular rubber pads 104 are fixed on the inner walls of the edge grooves 103, louver doors 105 are clamped in the edge grooves 103 on two sides of the mounting groove 102, and the louver doors 105 are tightly attached to the rubber pads 104 in the edge grooves 103;

the inside swing joint of mounting groove 102 has radiator unit 300, and radiator unit 300 includes mounting bracket 301, bearing 302 and fan structure 303, and mounting bracket 301 top and bottom all are connected with mounting groove 102's roof and diapire through bearing 302, and the intermediate position of mounting bracket 301 is fixed with fan structure 303.

Further, the mounting rack 301 comprises a ring plate 301a, a cross connection plate 301b and a round seat plate 301c, wherein the cross connection plate 301b is welded in the middle of the ring plate 301a, and the round seat plate 301c is welded in the middle of the back of the cross connection plate 301 b; the fan structure 303 includes a motor 303a, a connecting shaft 303b and fan blades 303c, wherein the shaft end of the motor 303a is connected with the connecting shaft 303b, and the fan blades 303c are connected to the connecting shaft 303 b.

Wherein, connecting shaft 303b crosses the central hole of cross connecting plate 301b, and motor 303a is fixed on the inner side of round seat plate 301 c.

The operation process comprises the following steps: when in use, the louver 105 on the front and the back of the installation groove 102 is pulled off, and then the installation frame 301 is rotated, so that the wind direction of the heat radiation assembly 300 can be changed according to the heat radiation requirement;

during monitoring, the motor 303a of the heat sink assembly 300 is activated by the button of the device host 100, causing the fan blades 303c to rotate at a high speed, thereby dissipating heat from the power environment surrounding the device host 100.

It should be noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present utility model may be modified or substituted without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered in the scope of the claims of the present utility model.

Claims (8)

1. The utility model provides a distributed power supply electricity generation ambient temperature real-time supervision equipment which characterized in that: comprising the steps of (a) a step of,

the device comprises a device host (100), wherein the bottom of the device host (100) is connected with a group of side-by-side temperature monitoring assemblies (200), and each temperature monitoring assembly (200) is electrically connected with a control module in the device host (100); the method comprises the steps of,

temperature monitoring subassembly (200), temperature monitoring subassembly (200) include temperature sensor (201), connecting block (202) and warning light (203), every temperature sensor's (201) detection end all is fixed with connecting block (202), one side of connecting block (202) is fixed with warning light (203).

2. The distributed power generation ambient temperature real-time monitoring device according to claim 1, wherein: a display screen (101) is fixed at the upper position of the front of the equipment host (100), and a mounting groove (102) is formed at the lower position of the equipment host (100).

3. The distributed power generation ambient temperature real-time monitoring device according to claim 2, wherein: edge grooves (103) are formed in the edges of the front face and the back face of the mounting groove (102), and annular rubber pads (104) are fixed on the inner walls of the edge grooves (103).

4. A distributed power generation ambient temperature real-time monitoring device according to claim 3, wherein: the louver door (105) is clamped in the side grooves (103) on two sides of the mounting groove (102), and the louver door (105) is tightly attached to the rubber pads (104) in the side grooves (103).

5. The distributed power generation ambient temperature real-time monitoring device according to claim 2, wherein: the inside swing joint of mounting groove (102) has radiator unit (300), radiator unit (300) include mounting bracket (301), bearing (302) and fan structure (303), mounting bracket (301) top and bottom all are connected with the roof and the diapire of mounting groove (102) through bearing (302), the intermediate position of mounting bracket (301) is fixed with fan structure (303).

6. The distributed power generation ambient temperature real-time monitoring device of claim 5, wherein: the mounting frame (301) comprises a ring plate (301 a), a cross connecting plate (301 b) and a round seat plate (301 c), wherein the cross connecting plate (301 b) is welded in the middle of the ring plate (301 a), and the round seat plate (301 c) is welded in the middle of the back of the cross connecting plate (301 b).

7. The distributed power generation ambient temperature real-time monitoring device of claim 5, wherein: the fan structure (303) comprises a motor (303 a), a connecting shaft (303 b) and fan blades (303 c), wherein the shaft end of the motor (303 a) is connected with the connecting shaft (303 b), and the fan blades (303 c) are connected to the connecting shaft (303 b).

8. The distributed power generation ambient temperature real-time monitoring device of claim 7, wherein: the connecting shaft (303 b) crosses the central hole of the cross connecting plate (301 b), and the motor (303 a) is fixed on the inner side surface of the round seat plate (301 c).