CN115848840B - Storage device is used in textile auxiliary production - Google Patents

Abstract

The application relates to the field of storage, the utility model relates to a storage device is used in textile auxiliary production, including being used for holding the storage pond that is equipped with the raw materials container, still include heating device, link to each other through the intercommunication water pipe between heating device and the storage pond, heating device includes the backup pad, set up the mounting groove of a plurality of indent in the backup pad, install the photovoltaic board in the mounting groove, backup pad cavity sets up, the inside chamber that holds that is used for storing circulating water of seting up of backup pad, hold the chamber and link to each other with the intercommunication water pipe, be equipped with the heating wire in the storage pond, photovoltaic board electric connection has the battery, battery and heating wire electric connection. Through setting up photovoltaic board, battery and heating wire, the water in the storage pool heats the intensification through the heat energy in the sunlight, and photovoltaic board converts the light energy in the sunlight into the electric energy and supplies power to the heating wire to make the temperature in the storage pool maintain at 70-80 ℃, a large amount of energy of utilizing the sunlight, the extra electric energy that consumes is less, thereby reaches energy-conserving effect.

Description

Storage device is used in textile auxiliary production

Technical Field

The application relates to the field of storage, in particular to a storage device for textile auxiliary production.

Background

Textile auxiliaries are chemicals which are necessary in the course of textile production and processing. The textile auxiliary can improve the softness, crease resistance, shrink resistance, water resistance, antibacterial property, antistatic property, flame retardance and other properties of textiles, can improve dyeing and finishing process, and has the effects of saving energy and reducing processing cost.

At present, textile auxiliary is usually prepared by mixing various raw materials. In order to maintain the liquid form of the raw materials, the raw materials are usually added into a storage device and stirred, so that the liquid form of the raw materials is maintained.

The related art can refer to Chinese patent publication No. CN210338705U and discloses a textile auxiliary storage device with anti-sedimentation function, which comprises a bottle body and a stirring device, wherein a containing cavity is arranged in the bottle body, the upper surface of the bottle body is convexly provided with a bottle opening, the bottle opening is communicated with the containing cavity, the stirring device is arranged on the side surface of the bottle body and extends into the containing cavity, a baffle plate is further arranged in the containing cavity, and the baffle plate extends from the bottle opening to the inner side surface of the bottle body and divides the containing cavity into a first cavity and a second cavity.

Because the raw materials need long-time storage, and adopt above-mentioned storage equipment to store the raw materials, equipment needs to be in the state of opening for a long time and constantly stirs the raw materials, and the energy consumption is higher, extravagant energy.

Disclosure of Invention

In order to solve the problems, the application provides a storage device for textile auxiliary production, which has the advantage of energy conservation.

The application provides a storage device is used in textile auxiliary production, adopts following technical scheme:

the utility model provides a textile auxiliary production is with storage device, is including being used for holding the storage pond that is equipped with the raw materials container, still includes heating device, links to each other through the intercommunication water pipe between heating device and the storage pond, and heating device includes the backup pad, a plurality of indent mounting groove has been seted up in the backup pad, and the mounting groove is embedded to have the photovoltaic board, backup pad cavity sets up, the inside holding chamber that is used for storing circulating water of seting up of backup pad, the holding chamber links to each other with the intercommunication water pipe, be equipped with the heating wire in the storage pond, photovoltaic board electric connection has the battery, battery and heating wire electric connection.

By adopting the technical scheme, the raw material tank filled with raw materials is arranged in the storage pool, and circulating water is injected into the storage pool and the accommodating cavity. In the daytime, sunlight irradiates on the photovoltaic panel, on the one hand, the photovoltaic panel absorbs solar energy and converts the solar energy into electric energy to be stored in the storage battery, on the other hand, the heat energy in the sunlight causes the temperature height of the photovoltaic panel, the heat of the photovoltaic panel is transferred to internal circulating water through the supporting plate, so that the circulating water is heated, the circulating water in the accommodating cavity is heated and then is transferred to the storage pool, and therefore the temperature in the storage pool is increased and maintained at 70-80 ℃. The raw material tank is placed in a higher environment, and the raw material is not easy to condense and precipitate when being heated. At night, the storage battery supplies power to the electric heating wire. The temperature of the storage pool is high, and the heating wire is used for heating and preserving the temperature of the circulating water in the storage pool, so that the temperature is maintained at 70-80 ℃, and the power consumption is low. Through setting up photovoltaic board, battery and heating wire, the water in the storage pool heats the intensification through the heat energy in the sunlight, and photovoltaic board converts the light energy in the sunlight into the electric energy and supplies power to the heating wire to make the temperature in the storage pool maintain at 70-80 ℃, a large amount of energy of utilizing the sunlight, the extra electric energy that consumes is less, thereby reaches energy-conserving effect.

Optionally, a plurality of heat transfer fins are fixed on the back of the photovoltaic panel, a plurality of heat transfer grooves opposite to the heat transfer fins are formed in the bottom of the mounting groove, and the heat transfer fins are inserted into the heat transfer grooves.

Through adopting above-mentioned technical scheme, the photovoltaic board absorbs heat and transmits for the backup pad through heat transfer fin, and heat transfer fin increases the area of contact of photovoltaic board and backup pad to improve the heat transfer effect.

Optionally, the one side sliding connection that the mounting groove was seted up to the backup pad has the connection frame that slip direction is mutually perpendicular with the backup pad, photovoltaic board installs on connection frame, set up the seal groove around backup pad a week in the backup pad, be fixed with the sealing piece of sliding connection in the seal groove on the connection frame, heat transfer fin's height is less than the height of sealing piece.

By adopting the technical scheme, in sunny days, the sunlight is sufficient, the photovoltaic panel is embedded in the mounting groove, the photovoltaic panel absorbs the solar energy sufficiently, the self temperature is higher, and the solar energy is transmitted to the supporting plate, so that the circulating water in the solar energy collector is heated. At night or on cloudy days, thereby photovoltaic board slides and breaks away from in the mounting groove and break away from with the backup pad and not contact with the backup pad, and at night or on cloudy days, lower temperature of surrounding environment causes the temperature of photovoltaic board to reduce, if photovoltaic board contact all the time with the backup pad can absorb circulating water's heat and give off in the air to lead to circulating water's heat to reduce and cause heat loss. Through the setting of connecting frame, the photovoltaic board links to each other with the backup pad is slided for the photovoltaic board can provide heat to circulating water, and can not too much absorb circulating water's heat, thereby guarantees circulating water's temperature, reduces heat loss.

Optionally, a heat insulation pad is fixed on one surface of the heat transfer fin away from the photovoltaic panel.

Through adopting above-mentioned technical scheme, when photovoltaic board from the mounting groove slip, heat transfer fin from the slip of heat transfer groove, until the heat insulating pad shutoff in the tip of heat transfer groove, the heat insulating pad is isolated backup pad and heat transfer fin, reduces heat loss.

Optionally, the sealing block is made of a thermal insulation material.

Through adopting above-mentioned technical scheme, connecting frame slides, when leading photovoltaic board to break away from in the mounting groove, and the sealing block slides out from the seal groove, and the sealing block is around in the backup pad, seals the edge of backup pad and photovoltaic board and shelters from, reduces the heat loss.

Optionally, be fixed with the electric putter that is used for controlling the slip of linking frame in the backup pad, electric putter one end links to each other with linking frame, and the other end links to each other with the backup pad.

Through adopting above-mentioned technical scheme, control the slip of linking frame through electric putter, simple structure, control is convenient.

Optionally, the one side that the connection frame deviates from the backup pad is fixed with photosensitive sensor, photosensitive sensor electric connection has the controller, controller and electric putter electric connection and control electric putter's motion.

Through adopting above-mentioned technical scheme, photosensitive sensor detects the illuminance of external environment, and when illuminance was lower, the electric putter of controller control, the connection frame drove the photovoltaic board and breaks away from in the mounting groove. When the illuminance is higher, the controller controls the electric push rod, and the connecting frame drives the photovoltaic panel to be embedded in the mounting groove, so that the automatic adjustment of the connecting frame is realized.

Optionally, be connected with circulating water pump on the intercommunication water pipe, hold the intracavity and be equipped with first temperature sensor, be equipped with second temperature sensor in the storage pond, first temperature sensor and second temperature sensor all with controller electric connection, controller and circulating water pump electric connection and control circulating water pump's start-stop.

Through adopting above-mentioned technical scheme, first temperature sensor and second temperature sensor detect the temperature of the circulating water of storage pool and holding intracavity respectively, and the controller compares both temperatures, if hold the temperature of intracavity and be higher than the water temperature in the storage pool, circulating water pump then starts, will hold the intracavity high temperature circulating water and drive into in the storage pool, if hold the intracavity temperature and be less than the water temperature in the storage pool, circulating water pump then stops the operation, reduces the loss of heat in the storage pool.

In summary, the present application includes at least one of the following beneficial technical effects:

1. through the arrangement of the photovoltaic panel and the storage pool, the photovoltaic panel absorbs and converts light energy and heat energy in solar energy, and the raw materials are stored in a heat-preserving way, so that the raw materials are not easy to condense and are always in a liquid state, the energy consumption is low, and the energy is saved;

2. through the setting of connecting frame, photovoltaic board and backup pad swing joint, when illumination intensity is higher, photovoltaic board temperature is higher, and photovoltaic board and backup pad laminating are supplied heat to the circulating water in the backup pad, and when illumination intensity is lower, photovoltaic board temperature is lower, and photovoltaic board breaks away from with the backup pad, reduces the thermal dissipation of circulating water in the backup pad.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the embodiment.

Fig. 2 is a schematic diagram showing connection of the support plate and the connection frame in the embodiment.

Reference numerals illustrate: 1. a storage pool; 11. heating wires; 2. a communicating water pipe; 21. a circulating water pump; 3. a support plate; 31. a mounting groove; 32. a receiving chamber; 33. a heat transfer tank; 34. sealing grooves; 4. a photovoltaic panel; 41. a storage battery; 42. a heat transfer fin; 5. a connection frame; 51. a sealing block; 61. an electric push rod; 62. a photosensitive sensor; 63. a controller; 64. a first temperature sensor; 65. and a second temperature sensor.

Description of the embodiments

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses storage device is used in textile auxiliary production, refer to fig. 1 and 2, including storage pool 1 and heating device that is equipped with the heat preservation, the storage pool 1 is stored with circulating water, links to each other through intercommunication water pipe 2 between heating device and the storage pool 1, is connected with circulating water pump 21 on the intercommunication water pipe 2. The heating device heats the circulating water, and the heated circulating water flows into the storage pool 1 to increase the temperature in the storage pool 1. The raw materials are stored in the storage pool 1, the temperature in the storage pool 1 is higher, and the raw materials are not easy to condense.

Referring to fig. 1 and 2, the heating apparatus includes a support plate 3, the support plate 3 is hollow, a receiving cavity 32 for storing circulating water is provided in the support plate 3, one end of a communicating water pipe 2 is communicated with the receiving cavity 32, and the other end is communicated with the inside of the storage tank 1. An electric heating wire 11 is arranged in the storage pool 1, and the electric heating wire 11 heats water in the storage pool 1 and keeps the water temperature in the storage pool 1.

Referring to fig. 1 and 2, a connection frame 5 having a sliding direction perpendicular to the support plate 3 is slidably coupled to the upper surface of the support plate 3, and a plurality of photovoltaic panels 4 are fixed to the connection frame 5. The photovoltaic panel 4 is electrically connected with a storage battery 41, the storage battery 41 is electrically connected with the electric heating wire 11, and the electric heating wire 11 is also connected with an external power supply in parallel. The photovoltaic panel 4 absorbs light energy in sunlight and converts the light energy into electric energy to be stored in the storage battery 41, and the storage battery 41 supplies power to the heating wire 11 to generate heat, so that the purpose of energy saving is achieved. When the energy supply of the storage battery 41 is insufficient due to insufficient illuminance or cloudy days, the external power supply can continuously supply energy to the heating wire 11 to ensure the normal use of the heating wire 11.

Referring to fig. 1 and 2, a plurality of mounting grooves 31 for accommodating the indent of the photovoltaic panel 4 are formed in one surface of the supporting plate 3 facing the photovoltaic panel 4, one surface of the mounting groove 31 is formed in the supporting plate 3, and heat insulation layers are arranged on the other surfaces, so that heat loss of the supporting plate 3 is reduced. The installation groove 31 is provided with a concave heat transfer groove 33. A plurality of heat transfer fins 42 corresponding to the heat transfer grooves 33 one by one are fixed on the surface of the photovoltaic panel 4 facing the mounting groove 31. During the daytime, the connecting frame 5 drives the photovoltaic panel 4 to slide, so that the photovoltaic panel 4 is embedded in the mounting groove 31, and the heat transfer fins 42 are inserted into the heat transfer grooves 33. While the photovoltaic panel 4 absorbs light energy, heat energy of sunlight is transferred to the support plate 3 through the heat transfer fins 42, thereby heating the circulating water in the support plate 3. At night, the sunlight is absent, the temperature is reduced, the connecting frame 5 drives the photovoltaic panel 4 to lift, the photovoltaic panel 4 is separated from the supporting plate 3, the heat transfer fins 42 are pulled out of the heat transfer grooves 33, and heat dissipation of circulating water through the photovoltaic panel 4 is reduced.

Referring to fig. 1 and 2, the circulating water is heated by thermal energy of solar energy during the daytime, and the optical energy is converted into electric energy to be stored in the storage battery 41. At night, the storage battery 41 supplies power to the heating wire 11, the heating wire 11 keeps the temperature of the water in the storage tank 1, and the solar energy utilization rate is high, so that the energy saving purpose is achieved.

Referring to fig. 1 and 2, a first temperature sensor 64 is disposed in the accommodating chamber 32, a second temperature sensor 65 is disposed in the storage tank 1, the first temperature sensor 64 is electrically connected to the controller 63, and the second temperature sensor 65 is also electrically connected to the controller 63. The controller 63 is electrically connected to the water circulation pump 21 and controls the start and stop of the water circulation pump 21. The first temperature sensor 64 and the second temperature sensor 65 detect the temperature of the circulating water in the accommodating cavity 32 and the storage tank 1 respectively, the controller 63 compares the temperature of the circulating water and the temperature of the circulating water, if the water temperature in the accommodating cavity 32 is higher than the water temperature in the storage tank 1, the circulating water pump 21 is started, the high-temperature circulating water in the accommodating cavity 32 is pumped into the storage tank 1, and if the water temperature in the accommodating cavity 32 is lower than the water temperature in the storage tank 1, the circulating water pump 21 stops running, so that the heat loss in the storage tank 1 is reduced.

Referring to fig. 1 and 2, a circle of annular sealing groove 34 is formed along the periphery of the supporting plate 3 on one surface of the supporting plate 3 facing the photovoltaic plate 4, a sealing block 51 which is connected in the sealing groove 34 in a sliding manner is fixed on one surface of the connecting frame 5 facing the supporting plate 3, and the sealing block 51 is made of heat insulation materials, such as a foam heat insulation plate and the like. The height of the heat transfer fins 42 is smaller than the height of the sealing block 51, that is, when the connecting frame 5 is completely lifted, the heat transfer fins 42 are completely pulled out from the heat transfer grooves 33, the heat transfer fins 42 are separated from the heat transfer grooves 33, and the photovoltaic panel 4 is suspended above the support plate 3 and is not in contact with the support plate 3, so that the heat transfer efficiency in the support plate 3 is reduced, and the heat loss is reduced. Moreover, the sealing block 51 seals the periphery of the connecting frame 5 and the supporting plate 3, so that the contact between the outside air and the supporting plate 3 is reduced, and the heat loss of the supporting plate 3 is further reduced.

Referring to fig. 1 and 2, a heat insulating pad is fixed to the side of the heat transfer fins 42 remote from the photovoltaic panel 4, and the heat insulating pad is always located in the heat transfer groove 33. When the photovoltaic panel 4 is pulled out of the mounting groove 31, the heat transfer fins 42 are pulled out of the heat transfer groove 33, the heat insulation pad is positioned at the end part of the heat transfer groove 33, and when the photovoltaic panel 4 moves towards the support plate 3 and is embedded in the mounting groove 31 again, the heat insulation pad can play a guiding role, so that the heat transfer fins 42 can be conveniently inserted.

Referring to fig. 1 and 2, at least one electric push rod 61 is fixed to a side of the support plate 3 facing the connection frame 5, and one end of the electric push rod 61 is connected to the connection frame 5 and the other end is connected to the support plate 3. The electric push rod 61 provides power to the movement of the connection frame 5.

Referring to fig. 1 and 2, a photosensitive sensor 62 is fixed on a surface of the connection frame 5 facing away from the support plate 3, the photosensitive sensor 62 is electrically connected with a controller 63, and the controller 63 is electrically connected with the electric push rod 61 and controls the movement of the electric push rod 61. The light sensor 62 detects the illuminance of the external environment, and when the illuminance is low, the controller 63 controls the electric push rod 61, and the connection frame 5 drives the photovoltaic panel 4 to be separated from the installation groove 31. When the illuminance is higher, the controller 63 controls the electric push rod 61, and the connecting frame 5 drives the photovoltaic panel 4 to be embedded in the mounting groove 31, so that the automatic adjustment of the connecting frame 5 is realized.

The implementation principle of the storage device for textile auxiliary production is as follows: when sunlight is sufficient in daytime, the photosensitive sensor 62 sends a signal to the controller 63, the controller 63 controls the electric push rod 61 to shrink, the photovoltaic panel 4 is embedded in the mounting groove 31, the photovoltaic panel 4 is attached to the support plate 3, heat absorbed by the photovoltaic panel 4 is transferred to circulating water in the support plate 3 through the heat transfer fins 42, and light energy absorbed by the photovoltaic panel 4 is converted into electric energy to be stored in the storage battery 41. The circulating water pump 21 is started to pump the circulating water with higher temperature in the supporting plate 3 into the storage pool 1, and pump the water with lower temperature in the storage pool 1 into the supporting plate 3 for heating, so that the water temperature in the storage pool 1 is at higher temperature, and the raw materials are stored.

At night, the illumination is lost, the electric push rod 61 is pushed up, the photovoltaic panel 4 is separated from the supporting plate 3, the storage battery 41 supplies power to the electric heating wire 11, and the electric heating wire 11 heats to keep warm and heat the water temperature in the storage tank 1.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (6)

1. Storage device for textile auxiliary production, comprising a storage tank (1) for containing raw material containers, characterized in that: the solar energy storage device is characterized by further comprising a heat supply device, wherein the heat supply device is connected with the storage tank (1) through a communication water pipe (2), the heat supply device comprises a support plate (3), a plurality of concave mounting grooves (31) are formed in the support plate (3), photovoltaic plates (4) are embedded in the mounting grooves (31), the support plate (3) is arranged in a hollow mode, a containing cavity (32) for storing circulating water is formed in the support plate (3), the containing cavity (32) is connected with the communication water pipe (2), heating wires (11) are arranged in the storage tank (1), the photovoltaic plates (4) are electrically connected with storage batteries (41), and the storage batteries (41) are electrically connected with the heating wires (11); a plurality of heat transfer fins (42) are fixed on the back of the photovoltaic panel (4), a plurality of heat transfer grooves (33) which are opposite to the heat transfer fins (42) are formed in the bottom of the mounting groove (31), and the heat transfer fins (42) are inserted into the heat transfer grooves (33); one side sliding connection that mounting groove (31) were seted up to backup pad (3) has connection frame (5) that slip direction is mutually perpendicular with backup pad (3), photovoltaic board (4) are installed on connection frame (5), set up seal groove (34) around backup pad (3) a week on backup pad (3), be fixed with sealing block (51) of sliding connection in seal groove (34) on connection frame (5), the height of heat transfer fin (42) is less than the height of sealing block (51).

2. A storage device for textile auxiliary production according to claim 1, characterized in that: and a heat insulation pad is fixed on one surface of the heat transfer fin (42) far away from the photovoltaic panel (4).

3. A storage device for textile auxiliary production according to claim 1, characterized in that: the sealing block (51) is made of a heat-insulating material.

4. A storage device for textile auxiliary production according to claim 1, characterized in that: an electric push rod (61) for controlling the connecting frame (5) to slide is fixed on the supporting plate (3), one end of the electric push rod (61) is connected with the connecting frame (5), and the other end of the electric push rod is connected with the supporting plate (3).

5. The storage device for textile auxiliary production according to claim 4, wherein: one surface of the connecting frame (5) deviating from the supporting plate (3) is fixedly provided with a photosensitive sensor (62), the photosensitive sensor (62) is electrically connected with a controller (63), and the controller (63) is electrically connected with the electric push rod (61) and controls the movement of the electric push rod (61).

6. The storage device for textile auxiliary production according to claim 5, wherein: be connected with circulating water pump (21) on intercommunication water pipe (2), be equipped with first temperature sensor (64) in holding chamber (32), be equipped with second temperature sensor (65) in storage pond (1), first temperature sensor (64) and second temperature sensor (65) all with controller (63) electric connection, controller (63) and circulating water pump (21) electric connection and control circulating water pump (21) start and stop.

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