CN204369852U - A kind of fermentor tank setting up temperature controlling instruments for the beer production main ferment phase - Google Patents

Abstract

A kind of fermentor tank setting up temperature controlling instruments for the beer production main ferment phase, conduit is provided with in cavity structure between the outer wall of described conical structure and inwall, the 3rd nichrome wire on the outside surface of the first chuck be conducted with conduit and the inwall being coiled in conical structure, described conduit is used for transmitting refrigerant, the first nichrome wire on the outside surface of the inwall being coiled in cylindrical structure is disposed with from top to bottom in outer wall in the middle part of described cylindrical structure and the cavity structure between inwall, the second nichrome wire on the outside surface of the second chuck be conducted with conduit and the inwall being coiled in cylindrical structure, such device avoids also not having like this in the defect that minimum temperature can not be occurred by the equipment that cooling jacket adjusts temperature lower than the main ferment stage of the condition of 8.5 DEG C of prior art.

Description

A kind of fermentor tank setting up temperature controlling instruments for the beer production main ferment phase

Technical field

The utility model belongs to the temperature controlling instruments technical field of beer production, is specifically related to a kind of fermentor tank setting up temperature controlling instruments for the beer production main ferment phase.

Background technology

In the main ferment stage of beer production, along with the acting in conjunction with fermentation batches, the phenomenon of distribute heat just can be there is thus under acting in conjunction, but the malconformation of distribute heat makes to arrange cooling jacket in the main ferment stage on fermentor tank lowers the temperature to allow main ferment stage keep normal temps, but cannot carry out can not adjusting temperature lower than the main ferment stage of the condition of 8.5 DEG C by cooling jacket in minimum temperature, and also do not have now to occur at the equipment that can not adjust temperature lower than the main ferment stage of the condition of 8.5 DEG C by cooling jacket in minimum temperature like this.

Summary of the invention

The purpose of this utility model provides a kind of fermentor tank setting up temperature controlling instruments for the beer production main ferment phase, comprise the support fixed with ground by bolt, the added outer hull being provided with hollow of described support, the bottom of described outer hull is the conical structure of pointed end, the top of described outer hull is the cylindrical structure that same conical structure is connected, one end of same first pipeline in bottom of described conical structure is connected and the empty internal of conical structure is conducted with the first pipeline, the other end of the first described pipeline is beer import, be cavity structure between the outer wall of outer hull and inwall in addition, conduit is provided with in cavity structure between the outer wall of described conical structure and inwall, the 3rd nichrome wire on the outside surface of the first chuck be conducted with conduit and the inwall being coiled in conical structure, described conduit is used for transmitting refrigerant, the first nichrome wire on the outside surface of the inwall being coiled in cylindrical structure is disposed with from top to bottom in outer wall in the middle part of described cylindrical structure and the cavity structure between inwall, the second nichrome wire on the outside surface of the second chuck be conducted with conduit and the inwall being coiled in cylindrical structure, the top of described outer hull is provided with pressure vessel head, the empty internal of the epimere of described outer hull is provided with the first hot resistance, the empty internal in the stage casing of described outer hull is provided with the second hot resistance, the empty internal of the hypomere of described outer hull is provided with the 3rd hot resistance, the terminal that one end of the first described hot resistance is 8 with the number designation of an XMTE-7000D intelligent digital temperature controller is connected, the terminal that the other end of the first described hot resistance is 7 with the number designation of an XMTE--7000D intelligent digital temperature controller is connected, the number designation of a described XMTE--7000D intelligent digital temperature controller be 1 terminal be connected with one end of the power supply of the first nichrome wire, one end of same first nichrome wire of the other end of the power supply of the first described nichrome wire is connected, the terminal that the other end of the first described nichrome wire is 2 with the number designation of a described XMTE--7000D intelligent digital temperature controller is connected, the terminal that one end of the second described hot resistance is 8 with the number designation of the 2nd XMTE-7000D intelligent digital temperature controller is connected, the terminal that the other end of the second described hot resistance is 7 with the number designation of the 2nd XMTE--7000D intelligent digital temperature controller is connected, the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller be 1 terminal be connected with one end of the power supply of the second nichrome wire, one end of same second nichrome wire of the other end of the power supply of the second described nichrome wire is connected, the terminal that the other end of the second described nichrome wire is 2 with the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller is connected, the terminal that one end of the 3rd described hot resistance is 8 with the number designation of the 3rd XMTE-7000D intelligent digital temperature controller is connected, the terminal that the other end of the 3rd described hot resistance is 7 with the number designation of the 3rd XMTE--7000D intelligent digital temperature controller is connected, the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller be 1 terminal be connected with one end of the power supply of the 3rd nichrome wire, one end of same 3rd nichrome wire of the other end of the power supply of the 3rd described nichrome wire is connected, the terminal that the other end of the 3rd described nichrome wire is 2 with the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller is connected.Such device avoids also not having like this in the defect that can not be occurred by the equipment that cooling jacket adjusts temperature lower than the main ferment stage of the condition of 8.5 DEG C in minimum temperature of prior art.

In order to overcome deficiency of the prior art, the utility model provides a kind of solution of setting up the fermentor tank of temperature controlling instruments for the beer production main ferment phase, specific as follows:

A kind of fermentor tank setting up temperature controlling instruments for the beer production main ferment phase, comprise the support 1 fixed with ground by bolt, the added outer hull 3 being provided with hollow of described support 1, the bottom of described outer hull 3 is the conical structure of pointed end, the top of described outer hull 3 is the cylindrical structure that same conical structure is connected, one end of same first pipeline 2 in bottom of described conical structure is connected and the empty internal of conical structure is conducted with the first pipeline 2, the other end of the first described pipeline 2 is beer import, be cavity structure between the outer wall of outer hull 3 and inwall in addition, conduit n1 is provided with in cavity structure between the outer wall of described conical structure and inwall, the 3rd nichrome wire 306 on the outside surface of the first chuck 4 be conducted with conduit and the inwall being coiled in conical structure, described conduit is used for transmitting refrigerant, the first nichrome wire 106 on the outside surface of the inwall being coiled in cylindrical structure is disposed with from top to bottom in outer wall in the middle part of described cylindrical structure and the cavity structure between inwall, the second nichrome wire 206 on the outside surface of the second chuck be conducted with conduit and the inwall being coiled in cylindrical structure, the top of described outer hull 3 is provided with pressure vessel head 8, the empty internal of the epimere of described outer hull 3 is provided with the first hot resistance 100, the empty internal in the stage casing of described outer hull is provided with the second hot resistance 200, the empty internal of the hypomere of described outer hull is provided with the 3rd hot resistance 300, the terminal that one end of the first described hot resistance 100 is 8 with the number designation of an XMTE-7000D intelligent digital temperature controller 101 is connected, the terminal that the other end of the first described hot resistance 100 is 7 with the number designation of an XMTE--7000D intelligent digital temperature controller 101 is connected, the number designation of a described XMTE--7000D intelligent digital temperature controller 101 be 1 terminal be connected with one end of the power supply 102 of the first nichrome wire, one end of same first nichrome wire 106 of the other end of the power supply 102 of the first described nichrome wire is connected, the terminal that the other end of the first described nichrome wire 106 is 2 with the number designation of a described XMTE--7000D intelligent digital temperature controller 101 is connected, the terminal that one end of the second described hot resistance 200 is 8 with the number designation of the 2nd XMTE-7000D intelligent digital temperature controller 201 is connected, the terminal that the other end of the second described hot resistance 200 is 7 with the number designation of the 2nd XMTE--7000D intelligent digital temperature controller 201 is connected, the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 be 1 terminal be connected with one end of the power supply 202 of the second nichrome wire, one end of same second nichrome wire 206 of the other end of the power supply 202 of the second described nichrome wire is connected, the terminal that the other end of the second described nichrome wire 206 is 2 with the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 is connected, the terminal that one end of the 3rd described hot resistance 300 is 8 with the number designation of the 3rd XMTE-7000D intelligent digital temperature controller 301 is connected, the terminal that the other end of the 3rd described hot resistance 300 is 7 with the number designation of the 3rd XMTE--7000D intelligent digital temperature controller 301 is connected, the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 be 1 terminal be connected with one end of the power supply 302 of the 3rd nichrome wire, one end of same 3rd nichrome wire 306 of the other end of the power supply 302 of the 3rd described nichrome wire is connected, the terminal that the other end of the 3rd described nichrome wire 306 is 2 with the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 is connected.

The described lower limit temperature set by an XMTE--7000D intelligent digital temperature controller 101 is 8.5 DEG C.

The described lower limit temperature set by the 2nd XMTE--7000D intelligent digital temperature controller 201 is 8.5 DEG C.

The described lower limit temperature set by the 3rd XMTE--7000D intelligent digital temperature controller 301 is 8.5 DEG C.

The first described hot resistance 100, second hot resistance 200 and the 3rd hot resistance 300 are platinum resistance thermometer sensor.

Application the utility model such scheme, tool has the following advantages:

By being provided with conduit n1 in the cavity structure between the outer wall of described conical structure and inwall, the 3rd nichrome wire 306 on the outside surface of the first chuck 4 be conducted with conduit and the inwall being coiled in conical structure, described conduit is used for transmitting refrigerant, the first nichrome wire 106 on the outside surface of the inwall being coiled in cylindrical structure is disposed with from top to bottom in outer wall in the middle part of described cylindrical structure and the cavity structure between inwall, the second nichrome wire 206 on the outside surface of the second chuck be conducted with conduit and the inwall being coiled in cylindrical structure, the top of described outer hull 3 is provided with pressure vessel head 8, the empty internal of the epimere of described outer hull 3 is provided with the first hot resistance 100, the empty internal in the stage casing of described outer hull is provided with the second hot resistance 200, the empty internal of the hypomere of described outer hull is provided with the 3rd hot resistance 300, the terminal that one end of the first described hot resistance 100 is 8 with the number designation of an XMTE-7000D intelligent digital temperature controller 101 is connected, the terminal that the other end of the first described hot resistance 100 is 7 with the number designation of an XMTE--7000D intelligent digital temperature controller 101 is connected, the number designation of a described XMTE--7000D intelligent digital temperature controller 101 be 1 terminal be connected with one end of the power supply 102 of the first nichrome wire, one end of same first nichrome wire 106 of the other end of the power supply 102 of the first described nichrome wire is connected, the terminal that the other end of the first described nichrome wire 106 is 2 with the number designation of a described XMTE--7000D intelligent digital temperature controller 101 is connected, the terminal that one end of the second described hot resistance 200 is 8 with the number designation of the 2nd XMTE-7000D intelligent digital temperature controller 201 is connected, the terminal that the other end of the second described hot resistance 200 is 7 with the number designation of the 2nd XMTE--7000D intelligent digital temperature controller 201 is connected, the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 be 1 terminal be connected with one end of the power supply 202 of the second nichrome wire, one end of same second nichrome wire 206 of the other end of the power supply 202 of the second described nichrome wire is connected, the terminal that the other end of the second described nichrome wire 206 is 2 with the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 is connected, the terminal that one end of the 3rd described hot resistance 300 is 8 with the number designation of the 3rd XMTE-7000D intelligent digital temperature controller 301 is connected, the terminal that the other end of the 3rd described hot resistance 300 is 7 with the number designation of the 3rd XMTE--7000D intelligent digital temperature controller 301 is connected, the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 be 1 terminal be connected with one end of the power supply 302 of the 3rd nichrome wire, one end of same 3rd nichrome wire 306 of the other end of the power supply 302 of the 3rd described nichrome wire is connected, the terminal that the other end of the 3rd described nichrome wire 306 is 2 with the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 is connected, can be just 8.5 DEG C at the lower limit temperature set by a described XMTE--7000D intelligent digital temperature controller 101, under the lower limit temperature of lower limit temperature set by 8.5 DEG C and the 3rd described XMTE--7000D intelligent digital temperature controller 301 set by the 2nd described XMTE--7000D intelligent digital temperature controller 201 be the condition of 8.5 DEG C, just can by connecting relevant electric wire circuit to generate heat after the temperature of the epimere in fermentor tank, stage casing and hypomere is lower than the lower limit temperature of setting, and once the temperature of epimere in fermentor tank, stage casing and hypomere has exceeded the lower limit temperature of setting, relevant electric wire circuit can be disconnected stop again heating.

Accompanying drawing explanation

Figure l is front view of the present utility model.

Embodiment

Below in conjunction with drawings and Examples, utility model content is described further:

As shown in Figure 1, for the fermentor tank setting up temperature controlling instruments of beer production main ferment phase, comprise the support 1 fixed with ground by bolt, the added outer hull 3 being provided with hollow of described support 1, the bottom of described outer hull 3 is the conical structure of pointed end, the top of described outer hull 3 is the cylindrical structure that same conical structure is connected, one end of same first pipeline 2 in bottom of described conical structure is connected and the empty internal of conical structure is conducted with the first pipeline 2, the other end of the first described pipeline 2 is beer import, be cavity structure between the outer wall of outer hull 3 and inwall in addition, conduit n1 is provided with in cavity structure between the outer wall of described conical structure and inwall, the 3rd nichrome wire 306 on the outside surface of the first chuck 4 be conducted with conduit and the inwall being coiled in conical structure, described conduit is used for transmitting refrigerant, the first nichrome wire 106 on the outside surface of the inwall being coiled in cylindrical structure is disposed with from top to bottom in outer wall in the middle part of described cylindrical structure and the cavity structure between inwall, the second nichrome wire 206 on the outside surface of the second chuck be conducted with conduit and the inwall being coiled in cylindrical structure, the top of described outer hull 3 is provided with pressure vessel head 8, the empty internal of the epimere of described outer hull 3 is provided with the first hot resistance 100, the empty internal in the stage casing of described outer hull is provided with the second hot resistance 200, the empty internal of the hypomere of described outer hull is provided with the 3rd hot resistance 300, the terminal that one end of the first described hot resistance 100 is 8 with the number designation of an XMTE-7000D intelligent digital temperature controller 101 is connected, the terminal that the other end of the first described hot resistance 100 is 7 with the number designation of an XMTE--7000D intelligent digital temperature controller 101 is connected, the number designation of a described XMTE--7000D intelligent digital temperature controller 101 be 1 terminal be connected with one end of the power supply 102 of the first nichrome wire, one end of same first nichrome wire 106 of the other end of the power supply 102 of the first described nichrome wire is connected, the terminal that the other end of the first described nichrome wire 106 is 2 with the number designation of a described XMTE--7000D intelligent digital temperature controller 101 is connected, the terminal that one end of the second described hot resistance 200 is 8 with the number designation of the 2nd XMTE-7000D intelligent digital temperature controller 201 is connected, the terminal that the other end of the second described hot resistance 200 is 7 with the number designation of the 2nd XMTE--7000D intelligent digital temperature controller 201 is connected, the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 be 1 terminal be connected with one end of the power supply 202 of the second nichrome wire, one end of same second nichrome wire 206 of the other end of the power supply 202 of the second described nichrome wire is connected, the terminal that the other end of the second described nichrome wire 206 is 2 with the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 is connected, the terminal that one end of the 3rd described hot resistance 300 is 8 with the number designation of the 3rd XMTE-7000D intelligent digital temperature controller 301 is connected, the terminal that the other end of the 3rd described hot resistance 300 is 7 with the number designation of the 3rd XMTE--7000D intelligent digital temperature controller 301 is connected, the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 be 1 terminal be connected with one end of the power supply 302 of the 3rd nichrome wire, one end of same 3rd nichrome wire 306 of the other end of the power supply 302 of the 3rd described nichrome wire is connected, the terminal that the other end of the 3rd described nichrome wire 306 is 2 with the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 is connected.The described lower limit temperature set by an XMTE--7000D intelligent digital temperature controller 101 is 8.5 DEG C.The described lower limit temperature set by the 2nd XMTE--7000D intelligent digital temperature controller 201 is 8.5 DEG C.The described lower limit temperature set by the 3rd XMTE--7000D intelligent digital temperature controller 301 is 8.5 DEG C.The first described hot resistance 100, second hot resistance 200 and the 3rd hot resistance 300 are platinum resistance thermometer sensor, the number designation of a described XMTE--7000D intelligent digital temperature controller 101 to be the terminal of 7 and the number designation of an XMTE-7000D intelligent digital temperature controller 101 be 8 terminal be used to the input aperture accessing the negative pole of hot resistance and the positive pole of hot resistance; The number designation of the 2nd XMTE--7000D intelligent digital temperature controller 201 to be the terminal of 7 and the number designation of the 2nd XMTE-7000D intelligent digital temperature controller 201 be 8 terminal be used to the input aperture accessing the negative pole of hot resistance and the positive pole of hot resistance; The number designation of the 3rd XMTE--7000D intelligent digital temperature controller 301 to be the terminal of 7 and the number designation of the 3rd XMTE-7000D intelligent digital temperature controller 301 be 8 terminal be used to the input aperture accessing the negative pole of hot resistance and the positive pole of hot resistance; The number designation of a described XMTE--7000D intelligent digital temperature controller 101 to be the terminal of 1 and the number designation of an XMTE--7000D intelligent digital temperature controller 101 be 2 the relay normally open contact delivery port that exports of the terminal lower limit temperature signal that just constitutes setting; The number designation of the 2nd described XMTE--7000D intelligent digital temperature controller 201 to be the terminal of 1 and the number designation of the 2nd XMTE--7000D intelligent digital temperature controller 201 be 2 the relay normally open contact delivery port that exports of the terminal lower limit temperature signal that just constitutes setting; The number designation of the 3rd described XMTE--7000D intelligent digital temperature controller 301 to be the terminal of 1 and the number designation of the 3rd XMTE--7000D intelligent digital temperature controller 301 be 2 the relay normally open contact delivery port that exports of the terminal lower limit temperature signal that just constitutes setting.

Principle of work of the present utility model is the main ferment phase in beer production, use the first chuck in fermentor tank and the second chuck to pass into refrigerant at conduit to lower the temperature, the first hot resistance 100 simultaneously by arranging at the empty internal of the epimere of described outer hull 3, the second hot resistance 200 that empty internal in the stage casing of described outer hull is arranged and the empty internal of the hypomere of described outer hull is provided with the temperature that the 3rd hot resistance 300 gathers the epimere of described outer hull 3 respectively, the temperature of the temperature in the stage casing of described outer hull 3 and the hypomere of described outer hull 3, and gather the temperature signal come and be sent to an XMTE--7000D intelligent digital temperature controller respectively, show in 2nd XMTE--7000D intelligent digital temperature controller and the 3rd XMTE--7000D intelligent digital temperature controller, so just can play the effect that staff can control each section of temperature of now fermentor tank in real time, if in addition at the empty internal of the epimere of main ferment phase inside and outside housing 3, if the empty internal of the hypomere of the empty internal in the stage casing of outer hull 3 or outer hull 3 is lower than the lower limit temperature of setting, like this by each self-corresponding first hot resistance 100, second hot resistance or the 3rd hot resistance just can be sent to an XMTE--7000D intelligent digital temperature controller the lower-limit temperature value lower than setting respectively in real time, in 2nd XMTE--7000D intelligent digital temperature controller or the 3rd XMTE--7000D intelligent digital temperature controller, the relay normally open contact delivery port that each self-corresponding lower limit temperature will be made like this to report to the police closes, the power supply connecting corresponding nichrome wire and nichrome wire thus heats, if reach after heating or exceeded the lower-limit temperature value of setting, like this by each self-corresponding first hot resistance 100, second hot resistance or the 3rd hot resistance just can be sent to an XMTE--7000D intelligent digital temperature controller reaching or having exceeded the lower-limit temperature value set respectively in real time, in 2nd XMTE--7000D intelligent digital temperature controller or the 3rd XMTE--7000D intelligent digital temperature controller, the relay normally open contact delivery port that each self-corresponding lower limit temperature will be made like this to report to the police recovers off-state, stop the heat-processed of the power supply of corresponding nichrome wire and nichrome wire thus.

The above, it is only preferred embodiment of the present utility model, not any pro forma restriction is done to the utility model, although the utility model discloses as above with preferred embodiment, but and be not used to limit the utility model, any those skilled in the art, do not departing within the scope of technical solutions of the utility model, make a little change when the technology contents of above-mentioned announcement can be utilized or be modified to the Equivalent embodiments of equivalent variations, in every case be do not depart from technical solutions of the utility model content, according to technical spirit of the present utility model, within spirit of the present utility model and principle, to any simple amendment that above embodiment is done, equivalent replacement and improvement etc., within the protection domain all still belonging to technical solutions of the utility model.

Claims (5)

1. the fermentor tank setting up temperature controlling instruments for the beer production main ferment phase, it is characterized in that comprising the support fixed with ground by bolt, the added outer hull being provided with hollow of described support, the bottom of described outer hull is the conical structure of pointed end, the top of described outer hull is the cylindrical structure that same conical structure is connected, one end of same first pipeline in bottom of described conical structure is connected and the empty internal of conical structure is conducted with the first pipeline, the other end of the first described pipeline is beer import, be cavity structure between the outer wall of outer hull and inwall in addition, conduit is provided with in cavity structure between the outer wall of described conical structure and inwall, the 3rd nichrome wire on the outside surface of the first chuck be conducted with conduit and the inwall being coiled in conical structure, described conduit is used for transmitting refrigerant, the first nichrome wire on the outside surface of the inwall being coiled in cylindrical structure is disposed with from top to bottom in outer wall in the middle part of described cylindrical structure and the cavity structure between inwall, the second nichrome wire on the outside surface of the second chuck be conducted with conduit and the inwall being coiled in cylindrical structure, the top of described outer hull is provided with pressure vessel head, the empty internal of the epimere of described outer hull is provided with the first hot resistance, the empty internal in the stage casing of described outer hull is provided with the second hot resistance, the empty internal of the hypomere of described outer hull is provided with the 3rd hot resistance, the terminal that one end of the first described hot resistance is 8 with the number designation of an XMTE-7000D intelligent digital temperature controller is connected, the terminal that the other end of the first described hot resistance is 7 with the number designation of an XMTE--7000D intelligent digital temperature controller is connected, the number designation of a described XMTE--7000D intelligent digital temperature controller be 1 terminal be connected with one end of the power supply of the first nichrome wire, one end of same first nichrome wire of the other end of the power supply of the first described nichrome wire is connected, the terminal that the other end of the first described nichrome wire is 2 with the number designation of a described XMTE--7000D intelligent digital temperature controller is connected, the terminal that one end of the second described hot resistance is 8 with the number designation of the 2nd XMTE-7000D intelligent digital temperature controller is connected, the terminal that the other end of the second described hot resistance is 7 with the number designation of the 2nd XMTE--7000D intelligent digital temperature controller is connected, the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller be 1 terminal be connected with one end of the power supply of the second nichrome wire, one end of same second nichrome wire of the other end of the power supply of the second described nichrome wire is connected, the terminal that the other end of the second described nichrome wire is 2 with the number designation of the 2nd described XMTE--7000D intelligent digital temperature controller is connected, the terminal that one end of the 3rd described hot resistance is 8 with the number designation of the 3rd XMTE-7000D intelligent digital temperature controller is connected, the terminal that the other end of the 3rd described hot resistance is 7 with the number designation of the 3rd XMTE--7000D intelligent digital temperature controller is connected, the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller be 1 terminal be connected with one end of the power supply of the 3rd nichrome wire, one end of same 3rd nichrome wire of the other end of the power supply of the 3rd described nichrome wire is connected, the terminal that the other end of the 3rd described nichrome wire is 2 with the number designation of the 3rd described XMTE--7000D intelligent digital temperature controller is connected.

2. the fermentor tank setting up temperature controlling instruments for the beer production main ferment phase according to claim 1, is characterized in that the described lower limit temperature set by an XMTE--7000D intelligent digital temperature controller is 8.5 DEG C.

3. the fermentor tank setting up temperature controlling instruments for the beer production main ferment phase according to claim 2, is characterized in that the described lower limit temperature set by the 2nd XMTE--7000D intelligent digital temperature controller is 8.5 DEG C.

4. the fermentor tank setting up temperature controlling instruments for the beer production main ferment phase according to claim 1, is characterized in that the described lower limit temperature set by the 3rd XMTE--7000D intelligent digital temperature controller is 8.5 DEG C.

5. the fermentor tank setting up temperature controlling instruments for the beer production main ferment phase according to claim 1, is characterized in that the first described hot resistance, the second hot resistance and the 3rd hot resistance are platinum resistance thermometer sensor.