CN217033056U - Cooker testing equipment - Google Patents

Abstract

The embodiment of the utility model discloses cooker testing equipment which comprises a cooker, a water pumping device, a first controller for controlling the water pumping device, a heating device and a second controller for controlling the heating device. The first controller controls the water pumping device to provide synchronous and uniform automatic water supply for the plurality of cookers, and the second controller controls the heater to provide synchronous and uniform heating effect for the plurality of cookers, so that the heating environment of the cookers is kept stable and unchanged, the result difference caused by different testing methods is reduced, and the consistency of the testing results is improved.

Description

Cooker testing equipment

Technical Field

The utility model relates to the technical field of cooker testing, in particular to cooker testing equipment.

Background

The cooker is used as a cooking tool for daily use, is closely related to daily diet of people, and needs to be subjected to strict quality detection. At present, the method and the requirement of the national standard for cooking the salt water by the cooker are listed in GB/T32388, but no test tool which can be used uniformly exists, so that the difference of the test result is large, and the accuracy is reduced.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a cooker testing device, which is used for solving the problem of large difference of the testing results of the brine boiling of the cooker in the prior art.

The utility model provides a cooker testing device, which is characterized by comprising the following components:

a plurality of cookers;

the water pumping device is used for adding water into the cooker;

a heating device that heats the cooker so that water in the cooker is in a boiling state;

the first controller is used for controlling the on-off of the water pumping device;

a second controller for controlling the heating power of the heating device;

when the second controller controls the heating device to work, the first controller controls the water pumping device to be powered on and supplies water to the cooker when the water level in the cooker is reduced, and when the second controller controls the heating device to stop heating, the first controller controls the water pumping device to be powered off.

Optionally, the water pumping device comprises a water pump, and the first controller comprises a timer, and the water pump is periodically powered on under the control of the timer, so that the water level in the cooker is maintained within a specified range.

Optionally, the time precision unit of the timer is second.

Optionally, the water level in the cooker is not lower than half the depth of the cooker.

Optionally, each water pumping device is used for supplying at least two cookers, and each cooker corresponds to one heating device.

Optionally, the input of the water pumping device is connected to a water taking source, the output of the water pumping device is connected to a water outlet pipe, the tail end of the water outlet pipe is connected to a plurality of branch pipes, and each branch pipe corresponds to one cooker one by one.

Optionally, the water intaking source includes the water storage bucket, be used for flourishing water in the water storage bucket, pumping device's input with the water storage bucket intercommunication.

Optionally, the water taking source further comprises a distilled water generator, the distilled water generator collects water vapor generated by boiling of water in the cooker and forms condensed water, and the condensed water flows into the water storage bucket and then is used by the water pumping device.

Optionally, the branch pipes are detachably connected to the water outlet pipe, that is, the number of the branch pipes connected to the water outlet pipe is variable.

Optionally, the second controller includes a power controller and a time controller, the power controller is configured to adjust a power output of the heating device, and the time controller is configured to adjust a power output duration of the heating device.

The embodiment of the utility model has the following beneficial effects:

in the cooker testing device, the cooker testing device comprises a cooker, a water pumping device, a first controller for controlling the water pumping device, a heating device and a second controller for controlling the heating device. The first controller controls the water pumping device to provide synchronous and uniform automatic water supply for the plurality of cookers, and the second controller controls the heater to provide synchronous and uniform heating effect for the plurality of cookers, so that the heating environment of the cookers is kept stable and unchanged, the result difference caused by different testing methods is reduced, and the consistency of the testing results is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Wherein:

FIG. 1 is a schematic diagram showing the construction of a cooker testing apparatus in one embodiment.

In the figure:

100. a cooker; 200. a water pumping device; 220. a first controller; 240. a water outlet pipe; 260. a branch pipe; 300. a heating device; 320. a second controller; 400. a water storage bucket.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The GB/T32388 lists parameter standards of national standards for cooking of salt water by cookers, and the utility model provides a cooker test device as a tool for testing the cooking of salt water by cookers, which can keep the heating environment of a cooker 100 stable and unchanged through a unified heating program and automatic water supply, reduce the result difference caused by different test methods and further improve the consistency of test results.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a cooker 100 testing apparatus in an embodiment, which includes a cooker 100, a pumping device 200, a first controller 220 for controlling the pumping device 200, a heating device 300, and a second controller 320 for controlling the heating device 300.

The cooker 100 is a product to be tested and contains water therein. The heating means 300 under the control of the second controller 320 heats the cooker 100 to ensure that the water in the cooker 100 is in a boiling state. The pumping means 200 under the control of the first controller 220 adds water to the cooker 100. Specifically, when the heating device 300 is operated, the pumping device 200 is controlled to be powered on and water is supplemented into the cooker 100 when the water level in the cooker 100 is lowered; when the heating device 300 stops heating, the water pumping device 200 is powered off to stop supplying water.

In the above embodiment, the second controller 320 controls the heating device 300 to start heating the cooker 100, and the brine inside the cooker 100 is heated to boiling. The water level is lowered by the gradual evaporation of moisture during the boiling of the brine, and the water pumping means 200 is operated to pump the external water into the cooker 100 to maintain the water level in the cooker 100.

Alternatively, the water level in the cooker 100 is maintained at more than half the depth of the cooker 100 by the supplement of the pumping device 200.

Illustratively, the water pumping device 200 includes a water pump, and the first controller 220 includes a timer. The timer is preprogrammed to control the water pump to be periodically energized, i.e., the pumping device 200 is operated at intervals, so that the water level in the cooker 100 is maintained within a designated range.

Preferably, the time unit of the timer of the present embodiment is accurate to seconds. The timer may be any control device that can pass through a time control circuit, such as a timer and a time relay.

Further, in order to save energy, the second controller 320 in this embodiment also has a preset program: the heating device 300 is controlled to start a full power or high power working state during the initial heating, and after the water in the cooker 100 is rapidly heated to be boiled, the heating device 300 is controlled to be switched to a half power or low power working state, so that the water in the cooker 100 is kept in a micro-boiling state.

Correspondingly, the second controller 320 includes a power controller for adjusting the power output of the heating apparatus 300 and a time controller for adjusting the power output duration of the heating apparatus 300.

Illustratively, when the heating device 300 is started, the water pumping device 200 is started to be in a standby state; the first 10 minutes is a high-power working state, and the working state is automatically switched to a low-power state after 10 minutes; starting the water pumping device 200 every 30 minutes from the time when the heating device 300 starts heating, and supplementing 200 ml of water into the cooker 100 every time; after 7 hours, the heating device 300 and the water pumping device 200 are powered off and stop working at the same time.

It should be noted that the above examples indicate that for the purpose of specifically describing the operation principle, specific data such as the interval time of the water pumping device 200, the volume of single water addition, etc. can be modified according to actual requirements.

As shown in fig. 1, in the above embodiment, each water pumping device 200 is used to supply at least two cookers 100, and each cooker 100 has one heating device 300. The plurality of heating devices 300 heat the cookers 100 at the same time, so that the heated states of the plurality of cookers 100 are uniform, and the difference of test results is reduced.

Optionally, the plurality of second controllers 320 may be preset with the same control program to ensure that the plurality of heating devices 300 operate in the same process.

Further, the same second controller 320 can control a plurality of heating devices 300 at the same time, further ensuring that the plurality of heating devices 300 work in the same process.

The heating device 300 according to this embodiment may be any heating device such as an induction cooker, an electric ceramic cooker, or a gas cooker.

Correspondingly, the input end of the water pumping device 200 is connected to a water taking source, the output end of the water pumping device 200 is connected to a water outlet pipe 240, the tail end of the water outlet pipe 240 is connected to a plurality of branch pipes 260, and each branch pipe 260 corresponds to one cooker 100 one by one. The pumping device 200 is activated to pump the water from the water supply source into the cooker 100 through each of the branch pipes 260.

Illustratively, the water intake source comprises a water storage barrel 400, the water storage barrel 400 is used for containing water, and the input end of the water pumping device 200 is communicated with the water storage barrel 400 to pump out the water in the water storage barrel 400.

Optionally, the water intake source further comprises a distilled water generator. The distilled water generator can collect water vapor generated by boiling water in the cooker 100 and form condensed water after condensation. The condensed water is collected and flows into the water storage tub 400 to be used by the pumping device 200. The evaporated water vapor is collected, so that the water in the whole test process can form closed loop for recycling, the energy is saved, and the environment is protected.

Optionally, the branch pipe 260 is detachably connected to the water outlet pipe 240, that is, the number of the branch pipes 260 connected to the water outlet pipe 240 is variable. How many cookers 100 of the same batch to be tested, correspondingly, several branch pipes 260 are installed.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention, and it is therefore to be understood that the utility model is not limited by the scope of the appended claims.

Claims (10)

1. A cookware testing apparatus, comprising:

a plurality of cookers;

the water pumping device is used for adding water into the cooker;

a heating device that heats the cooker so that water in the cooker is in a boiling state;

the first controller is used for controlling the on-off of the water pumping device;

a second controller for controlling a heating power of the heating device;

when the second controller controls the heating device to work, the first controller controls the water pumping device to be powered on and replenishes water into the cooker when the water level in the cooker is reduced, and when the second controller controls the heating device to stop heating, the first controller controls the water pumping device to be powered off.

2. The cookware test apparatus as claimed in claim 1 wherein the pumping means comprises a pump, the first controller including a timer, the pump being periodically energised under the control of the timer to maintain the level of water within the cookware within a specified range.

3. The cookware test apparatus of claim 2 wherein the timer has a time accuracy in seconds.

4. The cookware test apparatus of claim 2 wherein the level of water within the cookware is no less than half the depth of the cookware.

5. The cookware test rig of any one of claims 1 to 4 wherein each said pumping means is adapted to supply at least two said cookware, one said heating means for each cookware.

6. The cookware testing apparatus as claimed in claim 5, wherein an input end of said water pumping device is connected to a water source, an output end of said water pumping device is connected to a water outlet pipe, and a plurality of branch pipes are connected to the end of said water outlet pipe, each branch pipe corresponding to one cookware one by one.

7. The cookware test apparatus as claimed in claim 6 wherein said water source includes a water storage bucket for holding water, said water drawing means input communicating with said water storage bucket.

8. The cookware testing apparatus of claim 7 wherein said water source further comprises a distilled water generator, said distilled water generator collecting water vapor generated by boiling water in said cookware and forming condensed water, said condensed water flowing into said water storage bucket for use by said water extraction device.

9. Cooker testing device according to claim 6, characterised in that the branch is detachably connected to the outlet pipe, i.e. the number of branches connected to the outlet pipe is variable.

10. The cookware test apparatus set forth in claim 4 wherein said second controller includes a power controller for adjusting the magnitude of the power output of the heater and a time controller for adjusting the duration of the power output of the heater.

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