CN205361301U

CN205361301U - Energy -conserving reaction system

Info

Publication number: CN205361301U
Application number: CN201620047152.1U
Authority: CN
Inventors: 张佳训
Original assignee: Individual
Current assignee: Individual
Priority date: 2016-01-19
Filing date: 2016-01-19
Publication date: 2016-07-06
Anticipated expiration: 2026-01-19

Abstract

The utility model discloses an energy -conserving reaction system, be in including reation kettle and setting the outside energy -conserving heat accumulation system of reation kettle, energy -conserving heat accumulation system be in at the suit including setting up the casing in the reation kettle outside, the casing include inner housing and outer casing, inner housing with outer casing between be provided with the cavity the cavity in be provided with and adsorb heat storage materials, absorption heat storage materials be located the cavity be close to inner housing one side, the casing in be provided with and run through absorption heat storage materials's heat exchange pipeline, heat exchange pipeline by one side input of outer casing to from its opposite side output the reation kettle inboard be provided with several heating pipeline. The utility model discloses an adopting the heat that adsorbs the heat storage materials adsorption reaction in -process and produce, releasing when needs, the realization recycles heat energy, effectively reduces the energy consumption.

Description

A kind of energy-conservation response system

Technical field

The present invention relates to a kind of energy-conservation response system and energy-saving reverse induction method thereof.

Background technology

In chemical process; chemical reaction would generally produce heat; and in part chemical reaction process; need again to be heated heating, existing consersion unit, for the heat that reacting substance produces; would generally directly scatter and disappear; and when needing to heat, adopt again external heat source to be heated, waste very much the energy.

Summary of the invention

It is an object of the invention to provide a kind of energy-conservation response system and energy-saving reverse induction method thereof, prior art Problems existing can be improved, by adopting the heat produced in adsorptive heat-storage material adsorption reaction process, discharge when needed, realize the recycling to heat energy, effectively reduce energy consumption.

The present invention is achieved through the following technical solutions:

nullA kind of energy-conservation response system，Including reactor and be arranged on the energy-saving thermal storage system outside described reactor，Described energy-saving thermal storage system includes being arranged on the housing being sleeved on outside described reactor，Described housing includes internal layer shell and outer casing，It is provided with cavity between described internal layer shell and described outer casing，Adsorptive heat-storage material it is provided with in described cavity，Described adsorptive heat-storage material is positioned at described cavity near described internal layer shell side，The heat exchange pipe of described adsorptive heat-storage material it is provided through in described housing，The outer casing side input that described heat-exchange tube route is described，And export from its opposite side，It is provided with inside described reactor and several adds pipe line，The described pipe line that adds is connected by the outfan of electromagnetic valve with described heat exchange pipe respectively，Described add that pipe line is L-shaped to be positioned at inside described reactor，In described adding, pipe line is provided with several louvre，Described louvre is respectively arranged with check valve，Also include air preheater，It is provided with breather in described air preheater，Described breather is connected with the described pipe line that adds，Described breather is provided with Non-return air valve，It is provided with temperature measuring probe inside described reactor，Also include being arranged on the controller outside described outer casing，Described electromagnetic valve、Check valve、Non-return air valve、Temperature measuring probe is connected with described controller by circuit respectively.

Further, for realizing the present invention better, input and outfan at described heat exchange pipe are respectively arranged with temperature sensor, and described temperature sensor is connected with described controller respectively through circuit.

Further, for realizing the present invention better, described outer casing outer wall is provided with heat-insulation layer.

Further, for realizing the present invention better, being provided with booster pump outside described outer casing, described booster pump is positioned at described outer casing for heat exchange pipe input side one end, and described booster pump is connected with described controller by circuit.

The invention also discloses a kind of energy-saving reverse induction method, comprise the following steps:

S1: adopting temperature measuring probe detection reactor temperature, temperature data is sent to controller storage, when this temperature reaches reaction temperature, described electromagnetic valve, check valve, Non-return air valve all close；

S2: detect in step sl when reactor temperature does not reach design temperature, controller sends drive signal to Non-return air valve, check valve, makes Non-return air valve, check valve open, makes breather and add pipe line and input heated air in reactor；

S3: when adsorptive heat-storage material discharges heat, controller sends to electromagnetic valve and drives signal to make electromagnetic valve open, heat exchange pipe connects, and the cryogenic liquid in heat exchange pipe and adsorptive heat-storage material carry out heat exchange, input high-temp liquid by adding pipe line to reactor；

S4: detect that temperature reaches reaction temperature at temperature measuring probe, controller sends to Non-return air valve and drives signal, makes Non-return air valve close, and stops heat input.

The present invention compared with prior art, has the advantages that

The present invention chemical reaction process by being used for carrying out dispelling the heat at reactor, by adsorptive heat-storage material storing heat, in the chemical reaction needing heating, re-uses the heat of absorption, it is possible to effectively save the energy, improves efficiency of energy utilization；Invention can multiple field monitoring centers simultaneously, carry out integrated management, it is achieved when center controls multinode function, and efficiently accomplish resource consolidation, the equipment operation making each field node keeps optimum state, thus improving whole system to be in a kind of moderately good operational regime；Combine by automatic technology, intelligent control technology and microprocessor control technology and carry out system control, make machine in use can efficiently accomplish set workflow, improve process performance and the treatment effeciency of whole system, whole system is run more stable, and effectively reduce fault rate.

Accompanying drawing explanation

In order to be illustrated more clearly that the technical scheme of the embodiment of the present invention, the accompanying drawing used required in embodiment will be briefly described below, it is to be understood that, the following drawings illustrate only certain embodiments of the present invention, therefore the restriction to scope it is not construed as, for those of ordinary skill in the art, under the premise not paying creative work, it is also possible to obtain other relevant accompanying drawings according to these accompanying drawings.

Fig. 1 is overall structure schematic diagram of the present invention；

Fig. 2 is Control system architecture schematic diagram of the present invention.

Wherein: 101. reactors, 102. internal layer shells, 103. outer casings, 104. adsorptive heat-storage material, 105. heat exchange pipes, 106. add pipe line, 107. electromagnetic valve, 108. louvres, 109. check valves, 110. air preheater, 111. breather, 112. Non-return air valves, 113. controllers, 114. heat-insulation layer, 115. booster pumps.

Detailed description of the invention

Below in conjunction with specific embodiment, the present invention is described in further detail, but embodiments of the present invention are not limited to this.

Embodiment 1:

nullAs shown in Figure 1，A kind of energy-conservation response system，Including reactor 101 and be arranged on the energy-saving thermal storage system outside described reactor 101，Described energy-saving thermal storage system includes being arranged on the housing being sleeved on outside described reactor 101，Described housing includes internal layer shell 102 and outer casing 103，It is provided with cavity between described internal layer shell 102 and described outer casing 103，Adsorptive heat-storage material 104 it is provided with in described cavity，Described adsorptive heat-storage material 104 is positioned at described cavity near described internal layer shell 102 side，The heat exchange pipe 105 of described adsorptive heat-storage material 104 it is provided through in described housing，Described heat exchange pipe 105 is by described outer casing 103 side input，And export from its opposite side，It is provided with inside described reactor 101 and several adds pipe line 106，The described pipe line 106 that adds is connected by the outfan of electromagnetic valve 107 with described heat exchange pipe 105 respectively，Described add that pipe line 106 is L-shaped to be positioned at inside described reactor 101，In described adding, pipe line 106 is provided with several louvre 108，Described louvre 108 is respectively arranged with check valve 109，Also include air preheater 110，It is provided with breather 111 in described air preheater 110，Described breather 111 is connected with the described pipe line 106 that adds，Described breather 111 is provided with Non-return air valve 112，It is provided with temperature measuring probe inside described reactor 101，Also include being arranged on the controller 113 outside described outer casing 103，Described electromagnetic valve 107、Check valve 109、Non-return air valve 112、Temperature measuring probe is connected with described controller 113 by circuit respectively.

The present invention chemical reaction process by being used for carrying out dispelling the heat at reactor, by adsorptive heat-storage material storing heat, in the chemical reaction needing heating, re-uses the heat of absorption, it is possible to effectively save the energy, improves efficiency of energy utilization.

In the present embodiment, for the convenient input and output temperature detecting heat exchange pipe, convenient control, it is preferable that input and outfan at described heat exchange pipe 105 are respectively arranged with temperature sensor, and described temperature sensor is connected with described controller respectively through circuit.

In order to avoid heat spreader, in the present embodiment, it is preferable that be provided with heat-insulation layer 114 on described outer casing 103 outer wall.

In order to facilitate recycle heat, improve the pressure of heat exchange pipe, in the present embodiment, preferably, it is provided with booster pump 115 outside described outer casing 103, described booster pump 115 is positioned at described outer casing 103 for heat exchange pipe 105 input side one end, and described booster pump 115 is connected with described controller 113 by circuit.

Embodiment 2:

The present embodiment, on the basis of embodiment 1, the invention also discloses a kind of energy-saving reverse induction method, comprises the following steps:

S1: adopting temperature measuring probe detection reactor temperature, temperature data is sent to controller storage, when this temperature reaches reaction temperature, described electromagnetic valve 107, check valve 109, Non-return air valve 112 all close；

S2: detect in step sl when reactor temperature does not reach design temperature, controller sends drive signal to Non-return air valve 112, check valve 109, make Non-return air valve 112, check valve 109 open, make breather 111 and add pipe line 106 in reactor 101, input heated air；

S3: when adsorptive heat-storage material 104 discharges heat, controller 113 sends to electromagnetic valve 107 and drives signal to make electromagnetic valve 107 open, heat exchange pipe 105 connects, cryogenic liquid in heat exchange pipe and adsorptive heat-storage material 104 carry out heat exchange, input high-temp liquid by adding pipe line 106 to reactor 101；

S4: detect that temperature reaches reaction temperature at temperature measuring probe, controller 113 sends to Non-return air valve 112 and drives signal, makes Non-return air valve 112 close, and stops heat input.

The foregoing is only the preferred embodiments of the present invention, be not limited to the present invention, for a person skilled in the art, the present invention can have various modifications and variations.All within the spirit and principles in the present invention, any amendment of making, equivalent replacement, improvement etc., should be included within protection scope of the present invention.

Claims

null1. an energy-conservation response system，It is characterized in that: include reactor (101) and be arranged on the energy-saving thermal storage system that described reactor (101) is outside，Described energy-saving thermal storage system includes being arranged on the housing being sleeved on described reactor (101) outside，Described housing includes internal layer shell (102) and outer casing (103)，It is provided with cavity between described internal layer shell (102) and described outer casing (103)，Adsorptive heat-storage material (104) it is provided with in described cavity，Described adsorptive heat-storage material (104) is positioned at described cavity near described internal layer shell (102) side，The heat exchange pipe (105) of described adsorptive heat-storage material (104) it is provided through in described housing，Described heat exchange pipe (105) is by described outer casing (103) side input，And export from its opposite side，It is provided with in described reactor (101) inner side and several adds pipe line (106)，The described pipe line (106) that adds is connected by the outfan of electromagnetic valve (107) with described heat exchange pipe (105) respectively，Described add that pipe line (106) is L-shaped is positioned at described reactor (101) inner side，In described adding, pipe line (106) is provided with several louvre (108)，Described louvre (108) is respectively arranged with check valve (109)，Also include air preheater (110)，It is provided with breather (111) in described air preheater (110)，Described breather (111) is connected with the described pipe line (106) that adds，Described breather (111) is provided with Non-return air valve (112)，Described reactor (101) inner side is provided with temperature measuring probe，Also include the controller (113) being arranged on described outer casing (103) outside，Described electromagnetic valve (107)、Check valve (109)、Non-return air valve (112)、Temperature measuring probe is connected with described controller (113) by circuit respectively.
2. the energy-conservation response system of one according to claim 1, it is characterized in that: input and outfan at described heat exchange pipe (105) are respectively arranged with temperature sensor, and described temperature sensor is connected with described controller respectively through circuit.
3. the energy-conservation response system of one according to claim 1, it is characterised in that: on described outer casing (103) outer wall, it is provided with heat-insulation layer (114).
4. the energy-conservation response system of one according to claim 1, it is characterized in that: described outer casing (103) outside is provided with booster pump (115), described booster pump (115) is positioned at described outer casing (103) for heat exchange pipe (105) input side one end, and described booster pump (115) is connected with described controller (113) by circuit.