CN214371057U - Multi-loop miniature semiconductor refrigeration chip - Google Patents
Multi-loop miniature semiconductor refrigeration chip Download PDFInfo
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- CN214371057U CN214371057U CN202022770857.5U CN202022770857U CN214371057U CN 214371057 U CN214371057 U CN 214371057U CN 202022770857 U CN202022770857 U CN 202022770857U CN 214371057 U CN214371057 U CN 214371057U
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Abstract
The utility model discloses a miniature semiconductor refrigeration chip of multiloop, including bottom surface base plate, a plurality of work base plate and with the corresponding thermoelectric circuit of work base plate quantity, thermoelectric circuit sets up between work base plate and bottom surface base plate, and each thermoelectric circuit independently sets up, each work base plate non-contact. The utility model has the advantages that: the same bottom substrate is adopted, so that the overall dimension precision of the refrigeration chip is easier to control, the refrigeration chip is suitable for the field with strict requirements on the overall dimension, the independent working substrate and the thermoelectric circuit are arranged, and accurate refrigeration can be carried out on different heating points.
Description
Technical Field
The utility model relates to a thermoelectric module field especially relates to miniature semiconductor refrigeration chip of multiloop.
Background
Semiconductor refrigeration, also known as thermoelectric refrigeration, has been a discipline that has developed from the last 50 s that is at the edge of refrigeration and semiconductor technologies. The development of the semiconductor refrigerating and heating technology is nearly 100 years, and the technology is greatly popularized at home and abroad due to the advantages of multiple advantages, simple structure, no noise, no abrasion, no pollution, high reliability and high refrigerating speed.
At present, the refrigerating and heating chips at home and abroad are designed into a single loop, namely P-N pairs formed by semiconductors are utilized to form thermocouple pairs, a Peltier effect is generated, the thermocouple pairs are connected in series to form P-N pairs of thermopiles, after a power supply is switched on, heat at a cold end is transferred to a hot end, so that the temperature of the cold end is reduced, the temperature of the hot end is increased, and the aim of cooling or controlling the temperature of a target object is fulfilled. However, in the face of the inherent low refrigeration efficiency and increasingly stringent temperature control requirements of the semiconductor, the scheme of uniformly arranged PN pairs in the conventional manufacturing process is difficult to meet, especially in the communication field with more stringent requirements on space size and power consumption, when a heat source is concentrated in a local part, the heat resistance of heat transferred from the chip to a heat absorbing surface is large, and the heat source is usually based on the ideal assumption of uniform distribution of heat load in the design work, so that for the semiconductor refrigeration chip, the situation that the refrigeration and heating efficiency is not high even can not reach the design target value of temperature control performance. Most of the existing solutions adopt non-uniformly arranged PN pairs, but the PN pairs are still in a single loop, so that the performance optimization cannot be realized, or a plurality of semiconductor refrigeration chips are adopted for control, but the cost is that the overall dimension precision is reduced and the packaging process difficulty and complexity are increased, so that the contradiction is not fundamentally solved.
Disclosure of Invention
The utility model discloses mainly solved current refrigeration chip problem that refrigeration efficiency is low when the heat source is concentrated, provided one kind and be equipped with a plurality of thermoelectric circuit, adopted different thermoelectric circuit to the load part of difference for each regional load homoenergetic reaches the miniature semiconductor refrigeration chip in multiloop of optimization refrigeration performance.
The utility model provides a technical scheme that its technical problem adopted is, the miniature semiconductor refrigeration chip of multiloop, including bottom surface base plate, a plurality of work base plate and with the corresponding thermoelectric circuit of work base plate quantity, thermoelectric circuit sets up between work base plate and bottom surface base plate, and each thermoelectric circuit independently sets up, each work base plate non-contact each other.
The same bottom substrate is adopted, so that the overall dimension precision of the refrigeration chip is easier to control, the refrigeration chip is suitable for the field with strict requirements on the overall dimension, the independent working substrate and the thermoelectric circuit are arranged, and accurate refrigeration can be carried out on different heating points.
In a preferred embodiment of the present invention, the thermoelectric circuit is one or more of a cooling thermoelectric circuit for cooling the working substrate and a heating thermoelectric circuit for heating the working substrate. The refrigeration thermoelectric circuit is used for absorbing the heat of the heating point to realize the purpose of refrigeration, the heating thermoelectric circuit can meet different temperature control requirements, and meanwhile, the refrigeration efficiency of the refrigeration thermoelectric circuit is improved for absorbing the heat of the bottom substrate.
As a preferable mode of the above, the PN pair distribution density differs among the thermoelectric circuits. Different thermoelectric circuits have different refrigerating or heating efficiencies, and accurate temperature control is convenient for different parts.
As a preferable mode of the above, PN pairs in the same thermoelectric circuit are non-uniformly distributed.
As a preferable mode of the above-described mode, in two adjacent cooling thermoelectric circuits or heating thermoelectric circuits, the distribution density of PN pairs in the thermoelectric circuit increases as the distance from the other thermoelectric circuit increases. The interaction between two thermoelectric circuits of the same type is reduced, so that the thermoelectric circuits of the same type have higher working efficiency.
As a preferable mode of the above-described mode, in the two adjacent cooling thermoelectric circuits and heating thermoelectric circuits, the PN pair distribution density in the thermoelectric circuit decreases as the distance from the other thermoelectric circuit increases. The heat emitted by the cooling thermoelectric circuit on the bottom substrate can be better absorbed by the heating thermoelectric circuit, so that the two heat ground circuits are mutually assisted, and the working efficiency is improved.
The utility model has the advantages that: the same bottom substrate is adopted, so that the overall dimension precision of the refrigeration chip is easier to control, the refrigeration chip is suitable for the field with strict requirements on the overall dimension, the independent working substrate and the thermoelectric circuit are arranged, and accurate refrigeration can be carried out on different heating points.
Drawings
Fig. 1 is an exploded view of a multi-circuit micro semiconductor refrigeration chip according to an embodiment.
1-bottom substrate 2-work substrate 3-terminal 4-work substrate face conductor 5-bottom substrate face conductor 6-PN pair 7-conductor 8-thermistor.
Detailed Description
The technical solution of the present invention is further described below by way of examples and with reference to the accompanying drawings.
Example (b):
the multi-loop micro semiconductor refrigeration chip of the present embodiment, as shown in fig. 1, includes a bottom substrate 1, a plurality of working substrates 2, and thermoelectric circuits corresponding to the number of the working substrates, wherein the thermoelectric circuits are disposed between the working substrates and the bottom substrate, each thermoelectric circuit is independently disposed, and each working substrate is not in contact with each other. Thermoelectric circuit includes wiring end 3, work substrate face conductor 4, bottom surface basal plane conductor 5 and PN to 6, and work substrate face conductor sets up on the work substrate, and bottom surface basal plane conductor sets up on the bottom surface base plate, and between work substrate face conductor and the bottom surface basal plane conductor, the wiring end setting is on the bottom surface base plate, and the wiring end passes through conductor 7 and links to each other with bottom surface basal plane conductor.
The thermoelectric circuit can be divided into a refrigerating thermoelectric circuit and a heating thermoelectric circuit according to different connection modes of the PN pairs, wherein the refrigerating thermoelectric circuit refrigerates at the working substrate and releases heat at the bottom substrate; the heating thermoelectric circuit heats the working substrate and absorbs heat at the bottom substrate. One or more of the cooling thermoelectric circuit and the heating thermoelectric circuit can be selected as the thermoelectric circuit in the cooling chip according to different cooling and heating requirements.
According to different cooling or heating requirements, PN pairs in different thermoelectric circuits are different in density, for areas with high cooling or heating requirements, the PN pair density of the corresponding thermoelectric circuit is relatively higher, and conversely, for areas with low cooling or heating requirements, the PN pair density of the corresponding thermoelectric circuit is relatively lower. Meanwhile, the control of the working efficiency can be realized by accessing different working currents.
In the adjacent refrigerating thermoelectric circuits, the conductor of the refrigerating thermoelectric circuit with high PN pair density passes through the refrigerating thermoelectric circuit with low PN pair density, and a thermistor 8 is connected in series in the part of the conductor passing through the refrigerating thermoelectric circuit with low PN pair density. The thermistor can be a barium titanate PTC ceramic resistor, the inflection point temperature of the selected thermistor is the temperature of a heating surface under the low-efficiency working condition of the refrigerating thermoelectric circuit with low PN pair density, the limit temperature of the heating surface of the refrigerating thermoelectric circuit with high PN pair density is high, the quantity of heat emitted is large, the limit temperature of the heating surface of the refrigerating thermoelectric circuit with low PN pair density is relatively low, the quantity of heat emitted is relatively small, after the thermoelectric circuit runs for a long time, the heat emitted by the refrigerating thermoelectric circuit with high PN pair density is transferred to the refrigerating thermoelectric circuit with low PN pair density, so that the temperature of the bottom substrate is higher than the limit temperature of the heating surface of the refrigerating thermoelectric circuit with low PN pair density, the refrigerating thermoelectric circuit with low PN pair density cannot provide basic refrigerating function, at the moment, the resistance value of the thermistor is increased due to the temperature rise, and the working current of the thermoelectric circuit with high PN pair density is reduced, and then the heat release of the high PN pair density thermoelectric circuit on the bottom substrate is reduced, after a period of time, the temperature of the bottom substrate is reduced under the action of a radiator arranged outside the bottom substrate, the resistance value of the thermistor is reduced, and both the thermoelectric circuits can normally operate. ,
through the arrangement of the thermistor, when the temperature of the bottom substrate corresponding to the refrigerating thermoelectric circuit with low PN pair density is too high, the resistance of the conductor of the refrigerating thermoelectric circuit with high PN pair density is reduced, the working current is reduced, and the normal operation of the refrigerating thermoelectric circuit with low PN pair density is ensured.
PN in the thermoelectric circuits are distributed non-uniformly, the distribution density of the PN pairs in the thermoelectric circuits is increased along with the increase of the distance between the PN pairs and the other thermoelectric circuit, so that the phenomenon that the two thermoelectric circuits cannot have higher working efficiency due to too close heat release or heat absorption areas on the bottom substrate is avoided. In two adjacent thermoelectric circuits of different types, namely two adjacent heating thermoelectric circuits and cooling thermoelectric circuits, the distribution density of PN pairs in the thermoelectric circuits is reduced along with the distance from the other thermoelectric circuit, so that the heat emitted by the cooling thermoelectric circuit on the bottom substrate can be absorbed by the heating thermoelectric circuits as much as possible, and the two thermoelectric circuits are mutually assisted and have higher working efficiency.
The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.
Claims (6)
1. The multi-loop miniature semiconductor refrigeration chip is characterized in that: the thermoelectric module comprises a bottom substrate, a plurality of working substrates and thermoelectric circuits corresponding to the working substrates in number, wherein the thermoelectric circuits are arranged between the working substrates and the bottom substrate, the thermoelectric circuits are independently arranged, and the working substrates are not in contact with each other.
2. The multi-circuit miniature semiconductor refrigeration chip of claim 1 wherein: the thermoelectric circuit is one or more of a cooling thermoelectric circuit for cooling the working substrate and a heating thermoelectric circuit for heating the working substrate.
3. The multi-circuit miniature semiconductor refrigeration chip of claim 1 wherein: the PN pair distribution density varies among thermoelectric circuits.
4. The multi-circuit miniature semiconductor refrigeration chip of claim 2 wherein: PN pairs in the same thermoelectric circuit are non-uniformly distributed.
5. The multi-circuit miniature semiconductor refrigeration chip of claim 4 wherein: in two adjacent cooling thermoelectric circuits or heating thermoelectric circuits, the distribution density of PN pairs in the thermoelectric circuits increases with the distance from another thermoelectric circuit.
6. The multi-circuit miniature semiconductor refrigeration chip of claim 4 or 5, wherein: in two adjacent cooling thermoelectric circuits and heating thermoelectric circuits, the distribution density of PN pairs in the thermoelectric circuits decreases with the distance from the other thermoelectric circuit.
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