Energy online monitoring and diagnosing device
Technical Field
The utility model relates to a monitoring facilities field, in particular to energy on-line monitoring diagnostic device.
Background
The energy online monitoring and diagnosing device is an automatic system which collects various energy consumption data of energy consumption units in real time, generates a dynamic database through summarizing and analyzing, accurately reflects energy consumption and energy efficiency level of the energy consumption units in time, establishes a prediction and early warning analysis mechanism through an energy metering data platform, and realizes functions of energy-saving target management, diagnosis and the like. The existing energy online monitoring and diagnosing device has large data volume to be processed, so that the energy online monitoring and diagnosing device can generate a large amount of heat in the operation process, often causes overhigh temperature of the energy online monitoring and diagnosing device, influences the working stability of a monitoring and processing system, is easy to age and has short service life.
SUMMERY OF THE UTILITY MODEL
Based on this, it is necessary to provide an energy online monitoring and diagnosing device, including the protective housing with set up in the energy monitoring device body in the protective housing, two of protective housing all are provided with a plurality of louvres, the louvre is the array and arranges, still be provided with condenser tube on one of them side lateral wall that the protective housing was provided with the louvre, condenser tube is in proper order through each louvre.
Wherein, still be provided with the line hole of crossing that is used for the cable of energy monitoring devices body to pass through on the protective housing.
When the utility model is used, one side of the protective shell provided with the cooling water pipe faces to the windward direction, at the moment, wind enters the protective shell from the heat dissipation holes at the side of the protective shell and then blows out from the heat dissipation holes at the other side to take away heat in the protective shell, thereby reducing the temperature of the energy monitoring device body, in addition, the cooling water pipe is arranged at the opening of the heat dissipation holes at the windward side of the protective shell, therefore, when the wind is blown into the protective shell, the wind firstly exchanges heat with the cooling water pipe, thereby reducing the temperature of the air blown into the protective shell, the air with reduced temperature exchanges heat with the energy monitoring device, thereby accelerating the reduction of the temperature of the energy monitoring device and increasing the heat dissipation efficiency of the energy monitoring device, leading the heat dissipation effect of the energy monitoring device to be better, thereby avoiding overhigh working temperature of the energy monitoring device, and the normal operation of the energy monitoring device is ensured.
Preferably, the cooling water pipe is embedded in the side wall of the protective shell.
Inlay the condenser tube who establishes in the protective housing and can reduce the temperature exchange of condenser tube and environment to make it carry out the heat exchange with the protective housing more high-efficiently, with the temperature that reduces the protective housing, thereby further reduce the utility model discloses a temperature guarantees energy monitoring devices's normal operating.
Preferably, the protective housing is arranged at one end of the bottom plate, the other end of the bottom plate is further provided with a cooling water tank, and the cooling water tank corresponds to the cooling water pipe and is provided with a water inlet and a water outlet communicated with two ends of the cooling water pipe.
Further, the water outlet is located at the lower part of the cooling water tank, and the water inlet is located at the upper part of the cooling water tank.
The cooling water tank is used for providing the cooling water for condenser tube, and the water inlet is located cooling water tank's upper end, and the water that has passed through the heat exchange can flow back to cooling water tank's upper end for the hydrothermal layering of water cooling in the cooling water tank, and the lower extreme that the delivery port is located cooling water tank makes the temperature of the water that flows into condenser tube from the delivery port lower, can effectively improve the utility model discloses a cooling effect, wherein, cooling water tank can connect the compressor, and the compressor is used for refrigerating the cooling water in the cooling water tank.
Simultaneously, coolant tank and protective housing are integrated on same bottom plate, and are convenient for right the utility model discloses remove the transportation.
Furthermore, condenser tube includes into water end and play water end, it is located to advance water end the lower part of protective housing, it is located to go out water end the upper portion of protective housing.
The water inlet end is positioned at the lower part of the protective shell, so that cooling water can be filled in the cooling water pipe, and the heat exchange efficiency of the cooling water pipe, air and the protective shell is improved.
Further, the cooling water pipe is embedded in the bottom plate at a portion between the protective case and the cooling water tank.
The partial cooling water pipe is embedded in the bottom plate, so that heat exchange between the cooling water pipe and the environment can be reduced, and the temperature of cooling water in the cooling water pipe arranged on the protective shell is lower.
Furthermore, the fan is arranged on the bottom plate and located between the cooling water tank and the protective shell, the air outlet direction of the fan faces towards the protective shell, and one side, provided with the cooling water pipe, of the protective shell faces towards the cooling water tank.
The air-out direction of fan sets up towards the protective housing, and then the convulsions direction of fan is from coolant tank to the protective housing, then can make the temperature that the fan blew the air to the protective housing lower, can further reduce the temperature of protective housing.
Preferably, a water suction pump is arranged on the cooling water pipe.
The water pump is used for sending cooling water in the cooling water tank into the cooling water pipe and sending water in the cooling water pipe back into the cooling water tank to form a circulation.
The principle and effect of the present invention will be further explained by combining the above technical solutions:
when the utility model is used, one side of the protective shell provided with the cooling water pipe faces to the windward direction, at the moment, wind enters the protective shell from the heat dissipation holes at the side of the protective shell and then blows out from the heat dissipation holes at the other side to take away heat in the protective shell, thereby reducing the temperature of the energy monitoring device body, in addition, the cooling water pipe is arranged at the opening of the heat dissipation holes at the windward side of the protective shell, therefore, when the wind is blown into the protective shell, the wind firstly exchanges heat with the cooling water pipe, thereby reducing the temperature of the air blown into the protective shell, the air with reduced temperature exchanges heat with the energy monitoring device, thereby accelerating the reduction of the temperature of the energy monitoring device and increasing the heat dissipation efficiency of the energy monitoring device, leading the heat dissipation effect of the energy monitoring device to be better, thereby avoiding overhigh working temperature of the energy monitoring device, and the normal operation of the energy monitoring device is ensured.
Drawings
Fig. 1 is a schematic structural diagram of an energy online monitoring and diagnosing apparatus according to an embodiment of the present invention;
fig. 2 is a first schematic structural view of the protective shell according to the embodiment of the present invention;
fig. 3 is a schematic structural diagram of the protective shell according to the embodiment of the present invention.
Description of reference numerals:
1-protective shell, 11-radiating holes, 2-cooling water tank, 3-fan, 4-bottom plate, 5-cooling water pipe and 51-water pump.
Detailed Description
To facilitate understanding of those skilled in the art, the present invention will be described in further detail with reference to the accompanying drawings and examples:
as shown in fig. 1-3, an energy online monitoring and diagnosing apparatus includes a protective housing 1 and an energy monitoring apparatus body disposed in the protective housing 1, wherein a plurality of heat dissipation holes 11 are disposed on both sides of the protective housing 1, the heat dissipation holes 11 are arranged in an array, a cooling water pipe 5 is further disposed on a side wall of one side of the protective housing 1 where the heat dissipation holes 11 are disposed, and the cooling water pipe 5 sequentially passes through each heat dissipation hole 11.
Wherein, still be provided with the line hole of crossing that is used for the cable of energy monitoring devices body to pass through on the protective housing 1.
When the utility model is used, one side of the protective shell 1 provided with the cooling water pipe 5 faces the windward direction, at the moment, the wind enters the protective shell 1 from the heat dissipation holes 11 at the side of the protective shell 1 and then blows out from the heat dissipation holes 11 at the other side to take away the heat in the protective shell 1, thereby reducing the temperature of the energy monitoring device body, in the utility model, the cooling water pipe 5 is arranged at the opening of the heat dissipation holes 11 at the windward side of the protective shell 1, therefore, when the wind blows into the protective shell 1, the wind firstly exchanges heat with the cooling water pipe 5, thereby reducing the temperature of the air blown into the protective shell 1, the air with reduced temperature exchanges heat with the energy monitoring device, thereby accelerating the temperature reduction of the energy monitoring device and increasing the heat dissipation efficiency of the energy monitoring device, leading the heat dissipation effect of the energy monitoring device to be better, thereby avoiding the overhigh working temperature of the energy monitoring device, and the normal operation of the energy monitoring device is ensured.
In one embodiment, the cooling water pipe 5 is embedded in the side wall of the protective casing 1.
Inlay condenser tube 5 of establishing in protective housing 1 and can reduce condenser tube 5 and the temperature exchange of environment to make it carry out the heat exchange with protective housing 1 more high-efficiently, with the temperature that reduces protective housing 1, thereby further reduce the utility model discloses a temperature guarantees energy monitoring device's normal operating.
One of them embodiment, still include bottom plate 4, protective housing 1 set up in the one end of bottom plate 4, the other end of bottom plate 4 still is provided with coolant tank 2, coolant tank 2 corresponds coolant pipe 5 be provided with the water inlet and the delivery port of the both ends intercommunication of coolant pipe 5.
In one embodiment, the water outlet is located at the lower part of the cooling water tank 2, and the water inlet is located at the upper part of the cooling water tank 2.
Cooling water tank 2 is used for providing the cooling water for condenser tube 5, and the water inlet is located cooling water tank 2's upper end, and the water that has passed through the heat exchange can flow back to cooling water tank 2's upper end for the hydrothermal layering of cooling in cooling water tank 2, and the lower extreme that the delivery port is located cooling water tank 2 makes the temperature of the water that flows into condenser tube 5 from the delivery port lower, can effectively improve the utility model discloses a cooling effect, wherein, compressor can be connected to cooling water tank 2, and the compressor is arranged in refrigerating to the cooling water in cooling water tank 2.
Simultaneously, coolant tank 2 and protective housing 1 are integrated on same bottom plate 4, and are convenient for right the utility model discloses remove the transportation.
In one embodiment, the cooling water pipe 5 includes a water inlet end and a water outlet end, the water inlet end is located at the lower portion of the protective casing 1, and the water outlet end is located at the upper portion of the protective casing 1.
The lower part that the end is located the protective housing 1 of intaking can guarantee that the cooling water can be full of cooling water pipe 5, and then improves the heat exchange efficiency of cooling water pipe 5 and air and protective housing 1.
In one embodiment, the cooling water pipe 5 is embedded in the bottom plate 4 at a portion between the protective casing 1 and the cooling water tank 2.
The portion of the cooling water pipe 5 is buried in the bottom plate 4, and heat exchange of the cooling water pipe 5 with the environment can be reduced, thereby making the temperature of the cooling water in the cooling water pipe 5 provided on the protective case 1 lower.
One of the embodiments further comprises a fan 3, wherein the fan 3 is arranged on the bottom plate 4, the fan 3 is located between the cooling water tank 2 and the protective shell 1, the air outlet direction of the fan 3 faces the protective shell 1, and one side, provided with the cooling water pipe 5, of the protective shell 1 faces the cooling water tank.
The air-out direction of fan 3 sets up towards protective housing 1, and then fan 3's convulsions direction is from cooling water tank to protective housing 1, then can make the temperature of fan 3 air that blows to protective housing 1 lower, can further reduce the temperature of protective housing 1.
In one embodiment, a water pump 51 is disposed on the cooling water pipe 5.
The suction pump 51 is used for sending the cooling water in the cooling water tank into the cooling water pipe 5 and sending the water in the cooling water pipe 5 back into the cooling water tank 2 to form a circulation.
The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.